JP2022111300A - Radiographic apparatus and radiation image diagnostic system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To transfer image data of a radiation image that is not affected by noise in a short time without arranging a countermeasure member inside for preventing an influence of noise in a radiographic apparatus for transferring image data of a radiation image using a wireless device.

SOLUTION: A radiographic apparatus 100b includes: an image generation unit 2 for generating image data of a radiation image responding to a received radiation ray; a communication unit 3 having a wireless device 32 for wirelessly executing transmission/reception of data with another device 100c; a control unit 5 for controlling the image generation unit 2 and the communication unit 3; and a power source unit 6 for supplying power at least to the communication unit 3. The communication unit 3 includes a power adjusting part 33 for adjusting power so that a change with time of power consumed by the communication unit 3 is brought into a constant state or brought close to that state with power consumed when the wireless device 32 transmits the data while at least the image generation unit 2 is generating the image data.

SELECTED DRAWING: Figure 5

COPYRIGHT: (C)2022,JPO&INPIT

Description

The present invention relates to a radiographic apparatus and a radiographic image diagnosis system.

Noise occurs due to various factors inside an electronic device that generates image data or displays an image based on image data. Such noise causes deterioration of the quality of the displayed image or causes artifacts in the image.
Therefore, conventionally, various techniques have been proposed to reduce the influence of noise received when an electronic device generates or displays image data.
For example, Japanese Patent Application Laid-Open No. 2002-200000 discloses a technique for displaying a high-quality image that is not affected by voltage fluctuations by changing the output timing of a video signal when the voltage applied to a light-emitting element in a pixel fluctuates. An image display device capable of

Japanese Unexamined Patent Application Publication No. 2015-018138

One of the electronic devices that generate images is a portable radiation imaging apparatus that generates radiation images. In recent years, portable radiography equipment equipped with a wireless communication function has become necessary due to the need to improve portability and handling, and to improve the flexibility of the configuration of the radiographic imaging system including the radiography equipment. It's becoming commonplace.
In order to equip a portable radiographic imaging device with a wireless communication function, it is necessary to install a wireless device. is predefined. In other words, since the space for storing the wireless device is limited in the portable radiographic imaging apparatus, when the wireless device is mounted, it has to be placed close to the image generation unit that generates the image data. often not obtained.

When transferring large-sized data such as image data, a typical wireless device divides the data into multiple packets, and alternately transmits the packets and receives response information indicating that the packets have been received. repeat.
In addition, since the wireless device consumes more power during transmission than during reception, the current flowing through the wiring connecting the power supply circuit and the wireless device fluctuates when the transmission and reception are repeated. This current fluctuation causes a magnetic field fluctuation around the wiring, and the magnetic field fluctuation causes noise in an image generating unit arranged in close proximity, thereby degrading the image quality of the generated radiographic image.

However, when the technology described in Cited Document 1 is applied to a radiation imaging apparatus, it is possible to suppress the occurrence of noise caused by voltage fluctuations in the image generation unit, but the wireless devices placed close to each other may cause the noise. cannot cope with the noise generated in the image generation unit.
On the other hand, it is also conceivable to interpose a countermeasure member such as a high magnetic permeability sheet between the sensor unit and the wireless device, but space is limited in a portable radiation imaging apparatus. Therefore, in order to dispose the countermeasure member in a portable radiation imaging apparatus, the size of the housing must be increased, which makes it impossible to store the countermeasure member in an existing radiographic stand or the like.
Moreover, the use of such countermeasure members increases the number of parts used, resulting in an increase in the manufacturing cost of the radiation imaging apparatus.
It is also conceivable to restrict the transfer of image data while the image data is being generated. It's slowed down by the amount that generation and transfer can't be done in parallel.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems. It is an object of the present invention to transfer image data of radiation images that are not affected in a short period of time.

In order to solve the above problems, the radiographic apparatus of the present invention includes:
an image generation unit that generates image data of a radiographic image according to received radiation;
a communication unit having a wireless device that wirelessly transmits and receives data to and from another device;
a control unit that controls the image generation unit and the communication unit;
A power supply unit that supplies power to at least the communication unit,
At least while the image generating unit is generating image data, the communication unit maintains a change over time in power consumed by the communication unit at the power consumed when the wireless device transmits data. It is characterized by comprising a power adjustment unit that adjusts the state so that it becomes or approaches the state.

According to the present invention, it is possible to transfer image data of a radiographic image that is not affected by noise in a short period of time without arranging a countermeasure member for preventing the influence of noise.

1 is a block diagram showing a radiographic image diagnostic system according to an embodiment of the present invention; FIG. FIG. 2 is a perspective view of a radiographic apparatus included in the radiographic image diagnostic system of FIG. 1; 3 is a block diagram showing the radiation imaging apparatus of FIG. 2; FIG. FIG. 3 is a sectional view along IV-IV in FIG. 2; 3 is a block diagram showing a partial electrical configuration of the radiation imaging apparatus of FIG. 2; FIG. 3 is a flow chart showing state transition of the radiation imaging apparatus of FIG. 2; (a) is a graph showing the power consumption of the communication unit when the conventional radiation imaging apparatus transfers image data, and (b) is the power consumption of the communication unit when the radiation imaging apparatus according to the present embodiment transfers image data. 4 is a graph showing power;

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described with reference to the drawings. However, the invention is not limited to what is illustrated in the drawings.

[Configuration of radiographic image diagnosis system]
First, a schematic configuration of a radiographic image diagnostic system according to this embodiment will be described. FIG. 1 is a block diagram showing the configuration of a radiographic image diagnostic system 100 of this embodiment.
As shown in FIG. 1, the radiation image diagnostic system 100 includes a radiation generator 100a, a radiation imaging device 100b, and a console 100c.

The radiographic image diagnostic system 100 includes a hospital information system (HIS), a radiology information system (RIS), an image archiving and communication system (PACS), an image It may be possible to connect with an analysis device or the like.

Although not shown, the radiation generator 100a generates a voltage corresponding to preset radiation irradiation conditions (tube voltage, tube current, irradiation time (mAs value), etc.) when the irradiation instruction switch is pressed. and a radiation source that, when a voltage is applied from the generator, generates a dose of radiation (eg, X-rays) corresponding to the applied voltage.
The radiation generator 100a is adapted to generate radiation R (for example, X-rays) in a mode corresponding to radiographic images (still images/moving images) to be captured.

The radiation generating apparatus 100a may be installed in the imaging room, or may be configured to be movable together with the console 100c and the like, which is called a medical cart.

Then, the radiographic imaging apparatus 100b generates image data of a radiographic image according to the received dose of radiation.
The radiation imaging apparatus 100 b also includes a communication unit 3 , and can transfer generated image data to the console 100 c via the communication unit 3 .
Details of the radiation imaging apparatus 100b will be described later.

The console 100c is configured by a PC, a mobile terminal, or a dedicated device.
Also, the console 100 c includes a communication section 7 and a display section 8 .
The communication unit 7 can wirelessly receive the image data of the radiation image from the radiation imaging apparatus 100b.
The display unit 8 can display a radiation image based on the received image data.

The console 100c also has a function of setting various imaging conditions (tube voltage, tube current, irradiation time (mAs value), frame rate, etc.) for at least one of the radiation generator 100a and the radiation imaging apparatus 100b. there is
In addition, the console 100c has a function of instructing at least one of the radiation generating device 100a and the radiation imaging device 100b to capture a radiographic image (radiation irradiation and charge accumulation/readout) when the irradiation instruction switch is pressed. ing.
The console 100c also has a function of transmitting an image data transfer command to the radiation imaging apparatus 100b when triggered by a predetermined operation (for example, depression of an irradiation instruction switch, etc.) and an end of image data transfer when the transfer of image data is completed. It has a function of transmitting a command to the radiation imaging apparatus 100b.

In the present embodiment, the radiographic image diagnostic system 100 is provided with the console 100c. (The setting of imaging conditions, imaging instructions, and transmission/reception of commands may be performed from another device.).
Also, instead of the console 100c, an image analysis device that performs predetermined image processing on the received image data may be provided.
FIG. 1 illustrates a state in which the radiation imaging apparatus 100b and the console 100c are in direct wireless communication. good.

[Configuration of radiation imaging apparatus]
Next, the configuration of the radiation imaging apparatus 100b included in the radiation image diagnostic system 100 will be described. 2 is a perspective view of the radiation imaging apparatus 100b, FIG. 3 is a block diagram showing the radiation imaging apparatus 100b, and FIG. 4 is a sectional view taken along line IV-IV of FIG.
FIG. 2 illustrates a panel-shaped portable radiographic apparatus 100b, but the present invention is applicable to a so-called fixed type radiographic apparatus integrally formed with a support stand or the like. is also applicable.

As shown in FIGS. 2 to 4, the radiation imaging apparatus 100b includes a housing 1 and an image generation unit 2, a communication unit 3, a storage unit 4, and a control unit 5, which are housed in the housing 1. , and a power supply unit 6 .
Each part 1 to 6 is electrically connected.

A housing 1 according to the present embodiment is formed in a thin box shape (panel shape), and one of a plurality of surfaces is a radiation incident surface 11 .
A power switch 12, various operation switches 13, an indicator 14, a connector 15, and the like are provided on the side surface of the housing 1 adjacent to the radiation incident surface, as shown in FIG.

The image generating section 2 includes a scintillator 21 , a sensor section 22 , a scanning driving section 23 and a reading section 24 .
Each part 22 to 24 except the scintillator 21 is electrically connected.

The scintillator 21 is made of, for example, columnar crystals of CsI and formed in a flat plate shape.
Upon receiving radiation, the scintillator 21 emits an electromagnetic wave (for example, visible light) having a longer wavelength than the radiation with an intensity corresponding to the dose of the received radiation.
Moreover, the scintillator 21 is arranged in the housing 1 so as to extend parallel to the radiation entrance surface 11, as shown in FIG.

The sensor unit 22 has a two-dimensional array of pixels each having a detection element that generates an amount of charge corresponding to the intensity of the electromagnetic wave generated by the scintillator 21 and a switch element provided between each detection element and the wiring. It has a printed circuit board.
Further, the sensor section 22 is arranged on the opposite side of the scintillator 21 to the side where the radiation incident surface 11 exists, so as to spread parallel to the radiation incident surface 11 and the scintillator 21 .

The scanning drive unit 23 switches ON/OFF of each switch element.

The reading unit 24 reads the amount of charge accumulated in each pixel as a signal value, and generates image data of a radiographic image based on each signal value.

The communication unit 3 is composed of, for example, a wireless module.
The communication unit 3 wirelessly transmits and receives data and signals to and from another device (for example, the console 100c).
In addition, the communication unit 3 is provided close to the sensor unit 22 because the size of the housing 1 (especially the radiation entrance surface 11) must be able to be stored in an existing imaging table or the like (conforming to JIS standards). ing. In this embodiment, for example, as shown in FIG. 3, the sensor section 22 is arranged so as to be in contact with the surface of the sensor section 22 opposite to the side on which the scintillator 21 exists.
Details of the communication unit 3 will be described later.

The storage unit 4 is configured by an HDD (Hard Disk Drive), a semiconductor memory, or the like, and stores processing programs for executing various processes, parameters necessary for executing the processing programs, files, and the like.
Note that the storage unit 4 may be configured to store the image data of the generated radiographic image.

The control unit 5 includes a CPU (Central Processing Unit), a RAM (Random Access
Memory).
Then, the CPU reads out various processing programs stored in the storage unit 4, develops them in the RAM, and executes various processing according to the processing programs, thereby performing the radiation imaging apparatus 100b including the image generation unit 2 and the communication unit 3. It controls the operation of each part in an integrated manner.

The power supply section 6 includes a battery 61 and a power supply circuit 62 for the communication section 3 .
Moreover, the power supply unit 6 according to the present embodiment includes a power supply circuit for the image generation unit 2 (not shown).
The power supply unit 6 supplies power to each unit of the radiation imaging apparatus 100 b including at least the communication unit 3 .

[Configuration of communication unit]
Next, a specific configuration of the communication unit 3 included in the radiation imaging apparatus 100b will be described. FIG. 5 is a block diagram showing part of the electrical configuration (mainly the communication unit 3) of the radiation imaging apparatus 100b.

The communication unit 3 has a substrate 31, a wireless device 32, and a power adjustment unit 33, as shown in FIG.

The wireless device 32 wirelessly transmits and receives various data and various commands to and from another device (for example, the console 100c).
Further, when transferring large-sized data such as image data, the wireless device 32 according to the present embodiment divides the data into a plurality of packets, transmits the packets, and sends response information indicating that the packets have been received. Reception and , are alternately repeated.
Also, the wireless device 32 is connected to the power supply section 6 (power supply circuit 62) via the power adjustment section 33 (monitor section 33b, which will be described later).
Also, the wireless device 32 consumes different amounts of power when transmitting and receiving data. Specifically, relatively less power is consumed when receiving, and more power is consumed when transmitting than when receiving.
Hereinafter, the power consumed by the wireless device 32 when receiving data is referred to as first power, and the power consumed when transmitting data is referred to as second power.
Note that the second power does not have to be the power consumed during transmission, and may be greater than the first power within a range not exceeding the power consumed during transmission.

The power adjustment unit 33 according to this embodiment includes a power consumption unit 33a, a monitor unit 33b, an AND circuit 33c, and a switch unit 33d.

The power consumption section 33a is connected in parallel with the wireless device 32 to the power supply section 6 (power supply circuit 62) via the switch section 33d.
Also, the power consumption unit 33a consumes differential power, which is the difference between the second power and the first power.

The monitor unit 33b measures the power consumed by the wireless device 32 (the current flowing through the wiring connecting the power supply circuit 62 and the wireless device 32).
The monitor unit 33b also outputs a control signal to the AND circuit 33c, and switches between High and Low of the control signal according to the measured power consumption of the wireless device 32. FIG. Specifically, while the power consumption of the wireless device 32 is the second power (power consumption during transmission), the control signal is set to Low, and while the power consumption is the first power (power consumption during reception), the control signal is controlled. Make the signal high.
Note that the monitor unit 33b may not be provided on the substrate 31 (may be provided outside the communication unit 3).

The AND circuit 33c has two input terminals and one output terminal.
One input terminal of the AND circuit 33c receives the control signal from the control section 5, and the other input terminal receives the control signal from the monitor section 33b.
Also, the AND circuit 33c outputs a control signal from the output terminal to the switch section 33d, and switches between High/Low of the output signal according to the control signal input to the two input terminals. Specifically, while the control signal input from the control unit 5 is High and the control signal input from the monitor unit 33b is High, the output control signal is set to High. The control signal to be output is set to Low.

The switch section 33d switches ON/OFF according to the control signal input from the AND circuit 33c. Specifically, while the control signal input from the AND circuit 33c is High, it is turned on, and while it is Low, it is turned off.
As described above, the power consumption section 33a is connected in parallel with the wireless device 32 via the switch section 33d.

Further, the communication unit 3 in this embodiment is arranged so that the wireless device 32 and the power consumption unit 33a are close to the power supply unit 6 (power supply circuit 62).
Specifically, one end of the substrate 31 on which the wireless device 32 and the power consumption section 33 a are mounted is arranged so as to be adjacent to the power supply circuit 62 .
Therefore, the wiring that connects the power supply circuit 62 and the wireless device 32 and the wiring that connects the power supply circuit 62 and the power consumption unit 33a are not close to the power supply circuit 62. is shorter than Further, as a result, even if the current fluctuates inside the communication unit 3, the resulting magnetic field fluctuation is less likely to occur.

[Operation and effect of radiation imaging device]
Next, the operation and effects of the radiation imaging apparatus 100b will be described. FIG. 6 is a flowchart showing state transitions of the radiation imaging apparatus 100b, FIG. 7A is a graph showing power consumption of the communication unit when the conventional radiation imaging apparatus transfers image data, and FIG. 4 is a graph showing power consumption of the communication unit 3 when the radiation imaging apparatus 100b according to the embodiment transfers image data;

The control unit 5 according to the present embodiment configured as described above has a function of generating image data of a radiographic image according to the dose of the radiation R received on the radiation entrance surface 11, for example.
Specifically, first, the scanning driving section 23 turns off the switching elements to accumulate the charges generated by the respective detecting elements in the respective pixels, and then the scanning driving section 23 turns on the switching elements to accumulate the electric charges. The charge is output to the readout circuit. Then, the reading unit 24 is caused to read the signal value of each pixel, and image data is generated based on a plurality of signal values.

The control unit 5 also has a function of transmitting and receiving commands to and from another device (for example, the console 100 c ) via the communication unit 3 .
The control unit 5 also has a function of transferring the generated image data to another device via the communication unit 3 .

The control unit 5 also has a function of changing the operating state of the radiation imaging apparatus 100b. Note that this state transition is performed in parallel with the generation of image data.

First, when the power switch 12 is turned on, the radiation imaging apparatus 100b transitions to an image data untransferred state as shown in FIG. 6 (step S1).

In this state, the control unit 5 first uses the power supply circuit 62 to supply the standby current to the communication unit 3 .
Also, the control unit 5 sets the control signal output to the AND circuit 33c to Low.
Further, when the wireless device 32 is transmitting data (the power consumption is the second power), the monitor unit 33b sets the control signal output to the AND circuit 33c to Low to receive data. If (the power consumption is the first power), the control signal is set to High.
Since the control signal input from the control section 5 is Low, the AND circuit 33c in this state outputs a Low output signal to the switch section 33d regardless of the control signal input from the monitor section 33b. Therefore, the switch section 33d in this state is in a non-conducting state, and the power from the power supply circuit 62 is completely supplied to the wireless device 32 without being supplied to the power consumption section 33a.

Also, in this state, the control unit 5 monitors the reception status of the image data transfer command from another device (for example, the console 100c). Specifically, the determination of whether or not an image data transfer command has been received (step S2) is repeated.
That is, this image data untransferred state continues until the controller 5 determines that an image data transfer command has been received.

When the control unit 5 determines that an image data transfer command has been received in the image data non-transfer state (the wireless device 32 starts data transmission, step S2: Yes), the radiation imaging apparatus 100b transfers the first image data It transitions to the transfer state (step S3).

In this state, the controller 5 causes the image generator 2 to generate image data.
The control unit 5 uses the power supply circuit 62 to supply a current to the communication unit 3 during data transfer.
Also, the control unit 5 sets the control signal output to the AND circuit 33c to High.
In this state, since the wireless device 32 transmits data, the power consumption measured by the monitor section 33b becomes the second power, and the monitor section 33b sets the control signal output to the AND circuit 33c to Low.
Even if the control signal input from the control unit 5 is High, the AND circuit 33c in this state sets the output signal output to the switch unit 33d to Low because the control signal input from the monitor unit 33b is Low. do. Therefore, the switch section 33d in this state is turned off, and all the power from the power supply circuit 62 is supplied to the wireless device 32 without being supplied to the power consumption section 33a.
That is, the control unit 5 switches the switch unit 33d to the non-conducting state (OFF) when the power measured by the monitor unit 33b is the second power.

In this state, the power consumption of the entire communication unit 3 is the power consumption of the wireless device 32 during transmission (second power).

This first image data transfer state continues while the wireless device 32 is transmitting data (while the power consumption of the wireless device 32 measured by the monitor 33b is the first power).

When the first image data transfer state of the wireless device 32 ends (the power consumption of the wireless device becomes the first power, step S4: Yes), the radiation imaging apparatus 100b transitions to the second image data transfer state (step S5).

The control unit 5 causes the image generation unit 2 to generate image data even in this state.
Further, the control unit 5 uses the power supply circuit 62 to supply the current to the communication unit 3 during data transfer.
Also in this state, the control unit 5 sets the control signal output to the AND circuit 33c to Hi.
make it gh.
In this state, since the wireless device 32 receives data, the power consumption measured by the monitor section 33b becomes the first power, and the monitor section 33b sets the control signal output to the AND circuit 33c to High.
In this state, the AND circuit 33c outputs a high signal to the switch section 33d because both the control signal input from the control section 5 and the control signal input from the monitor section 33b are high. Therefore, the switch section 33d in this state is turned on, and the power from the power supply circuit 62 is supplied not only to the wireless device 32 but also to the power consumption section 33a.
That is, the control unit 5 switches the switch unit 33d to the conductive state (ON) when the power measured by the monitor unit 33b is the first power.

As described above, the power consumption section 33a according to the present embodiment consumes differential power, which is the difference between the second power and the first power.
Therefore, in this state, the power consumed by the entire communication unit 3 is: power consumption during reception by the wireless device 32 (first power) + power consumption by the power consumption unit 33a (second power - first power) = This is the power consumption (second power) during transmission of the wireless device 32, and is equal to the power consumption of the entire communication unit 3 in the first image data transfer state.

This second image data transfer state continues while the wireless device 32 is receiving data (while the power consumption of the wireless device 32 measured by the monitor 33b is the second power).

Also, in this state, the control unit 5 monitors the reception status of the image data transfer end command from another device (for example, the console 100c). Specifically, the determination of whether or not an image data transfer end command has been received (step S6) is repeated.
When transferring image data, the wireless device 32 repeats data transmission and reception. It is repeated alternately until

By alternately repeating the first image data transfer state and the second image data transmission state, the power adjustment unit 33 controls the power consumed by the communication unit 3 at least while the image generation unit 2 is generating image data. is adjusted so that the power consumed by the wireless device 32 when transmitting data remains constant.
Note that when the second power is set lower than the power consumption during data transmission, the power consumption of the communication unit 3 is reduced when the first image data transfer state and the second image data transmission state are alternately repeated. not constant. However, since the second power is closer to the power consumption during data transmission than the first power, the change over time of the power consumed by the communication unit 3 is constant compared to the case where the power adjustment unit 33 is not provided. will be adjusted to approach

When the control unit 5 determines that the image data transfer end command is received in the first image data transfer state or the second image data transfer state (step S6; Yes), the radiation imaging apparatus 100b transitions to the image data non-transfer state. do.

A typical wireless device including the wireless device 32 according to this embodiment repeats transmission and reception when transferring large-sized image data.
Moreover, as described above, the power consumption of the communication unit differs between transmission and reception as shown in FIG.
If the distance between the image generator and the wireless device is long, the change in the magnetic field has a negligible effect on the image data. However, when there is a restriction on the size of the housing (the radiation imaging apparatus 100b is portable as in this embodiment), the wireless device 32 is placed close to the image generation unit 2 as shown in FIG. Therefore, when the image generating unit 2 generates image data, it is affected by fluctuations in the magnetic field, and horizontal streaks occur in the radiographic image.

However, in the radiation imaging apparatus 100b according to the present embodiment, the power consumption of the communication unit 3 in the second image data transfer state (when the wireless device 32 receives data) is less than that in the first image data transfer state ( When the wireless device 32 transmits data), the power consumption of the communication unit 3 is equal to the second power, that is, the power consumption of the communication unit 3 is constant at the second power throughout the transfer period. Therefore, the current flowing through the wiring does not fluctuate, and the magnetic field does not change accordingly, so that noise does not occur in the image generating section that generates image data in parallel with the transfer of image data. As a result, it is possible to prevent horizontal streaks from occurring in the radiographic image displayed on the display unit 8 of the console 100c to which the image data is transferred.

Further, even if image data generation and image data transfer are performed in parallel, horizontal streaks do not appear in the radiographic image, so there is no need to take measures such as regulating the transfer of image data while the radiographic image is being generated. Therefore, it is possible to prevent the radiographic image display on the console 100c from being delayed due to the inability to perform image data generation and image data transfer in parallel.
In addition, since there is no need to arrange a countermeasure member such as a high magnetic permeability sheet between the image generation unit 2 and the communication unit 3, there is no need to increase the size of the housing 1 in order to secure the installation space. An increase in manufacturing cost can be suppressed by the amount that does not increase the number of parts.
That is, according to the radiation imaging apparatus 100b according to the present embodiment, it is possible to transfer image data of a radiographic image that is not affected by noise in a short period of time without arranging a countermeasure member for preventing the influence of noise. can.

Moreover, the radiation imaging apparatus 100b according to the present embodiment drives the power adjustment unit 33 only in the first image data transfer state and the second image data transfer state in which image data is generated and transferred in parallel. That is, the power adjustment unit 33 is not driven in the image data non-transfer state in which image data is not generated (no noise is added to the image data even if the power consumption of the wireless device 32 fluctuates). For this reason, the battery 61 can be extended by the amount that the power consumption unit 33a does not consume power during the period in which the image data is not transferred.

Although the present invention has been specifically described above based on the embodiments, it goes without saying that the present invention is not limited to the above embodiments, and can be modified as appropriate without departing from the scope of the invention.

For example, in the above embodiments, the combination of the radiation imaging apparatus 100b and the console 100c has been described as an example, but the present invention is applicable to electronic devices in general that wirelessly transmit and receive image data and electrically generate or display images. It is possible to That is, it can be applied to a combination of a digital camera and a PC or a tablet terminal.

In the above embodiment, the AND circuit 33c is used to switch ON/OFF of the switch section 33d. may be performed directly.

REFERENCE SIGNS LIST 100 Radiographic image diagnostic system 100a Radiation generator 100b Radiation imaging device 1 Housing 11 Radiation incident surface 12 Power switch 13 Operation switch 14 Indicator 15 Connector 2 Image generation unit 21 Scintillator 22 Sensor unit 23 Scanning drive unit 24 Readout unit 3 Communication unit 31 Substrate 32 Wireless device 33 Power adjustment unit 33a Power consumption unit 33b Monitor unit 33c Switch unit 33d AND circuit 4 Storage unit 5 Control unit 6 Power supply unit 61 Battery 62 Power supply circuit 100c Console 7 Communication unit 8 Display unit

In order to solve the above problems, the radiographic apparatus of the present invention includes:
an image generation unit that generates image data of a radiographic image corresponding to radiation ;
a communication unit having a wireless device that wirelessly transmits and receives data to and from another device;
a control unit that controls the image generation unit and the communication unit;
A power supply unit that supplies power to at least the communication unit,
The communication unit includes a power adjustment unit that adjusts a change over time in power consumed by the communication unit at least while the image generation unit is generating image data ,
The communication unit is characterized by having a power saving period during which power consumption is less than that during transmission and reception during at least part of a period during which the image data is not generated .

Claims (4)

an image generation unit that generates image data of a radiographic image according to received radiation;
a communication unit having a wireless device that wirelessly transmits and receives data to and from another device;
a control unit that controls the image generation unit and the communication unit;
A power supply unit that supplies power to at least the communication unit,
At least while the image generating unit is generating image data, the communication unit maintains a change over time in power consumed by the communication unit at the power consumed when the wireless device transmits data. A radiation imaging apparatus, comprising: a power adjustment unit that adjusts the state so as to be close to or close to the state. The power adjustment unit
connected in parallel with the wireless device via a switch unit, and consumes differential power that is the difference between the first power and a second power that is larger than the first power consumed by the wireless device when receiving data a power consumer that
a monitor unit that monitors the power consumed by the wireless device,
The control unit
switching the switch unit to a non-conducting state when the power measured by the monitor unit is the second power;
2. The radiation imaging apparatus according to claim 1, wherein the switch section is switched to a conducting state when the power measured by the monitor section is the first power. 3. The radiation imaging apparatus according to claim 2, wherein the communication unit is arranged such that the wireless device and the power consumption unit are close to the power supply unit. a radiation imaging apparatus according to any one of claims 1 to 3;
A radiographic image diagnostic system, comprising: an image display device having a communication unit that wirelessly receives image data of a radiographic image from the radiographic apparatus; and a display unit that displays a radiographic image based on the received image data.

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