WO2019150765A1 - Radiographic imaging device, imaging control device, radiographic imaging system, and control method therefor - Google Patents

Abstract

This radiographic imaging system is provided with a radiographic imaging device and a communication unit for providing a communication connection with the radiographic imaging device, wherein the radiographic imaging device transmits a radiographic image obtained by imaging to an imaging control device via the communication connection provided by the communication unit, generates and stores a log in a log storage unit, and transmits the log stored in the log storage unit to the imaging control device via the communication connection provided by the communication unit in response to a predetermined event that gives rise to the occurrence of a log update. The imaging control device receives the radiographic image and the log, and stores the received radiographic image and log in a storage unit.

Description

Radiation imaging apparatus, imaging control apparatus, radiation imaging system, and control method therefor

The present invention relates to a radiation imaging apparatus, an imaging control apparatus, a radiation imaging system, and a control method thereof.

Currently, radiation imaging devices are adopting wireless communication for communication with control devices, and are becoming increasingly portable. In the communication between the radiation generating device and the control device, the radiation imaging device sends to the control device the transmission of the captured image, the remaining battery level of the imaging device, the state of the imaging device (whether it can be imaged), error information, etc. send. Further, the control device sends operation instructions, setting information, and the like to the radiation imaging apparatus.

Patent Document 1 describes a configuration in which data stored in a radiation imaging apparatus is extracted when the radiation imaging apparatus fails. Patent Document 2 describes a configuration in which the state of an apparatus can be confirmed in a portable radiation imaging apparatus.

JP 2016-052357 A JP 2008-145101A

As radiation imaging devices become portable, it is important to save operation logs (hereinafter referred to as logs) of radiation imaging devices for maintenance and service. A log is a set of history (hereinafter, log items) such as operation information arranged in time series. In general, the log is stored in a memory in the radiation imaging apparatus and is extracted as needed by a specific user operation for maintenance. If the log items are left in detail, the operation can be clearly understood, so it can be said that the log volume can be increased. However, the amount of logs that can be stored is limited by the capacity of the memory in the radiation imaging apparatus. Therefore, when the memory capacity for recording the log is used up, the past log is overwritten with the subsequent log, and all the logs cannot be left.

When an abnormality occurs on site, a service person obtains an image or log at the time of abnormality from the memory and analyzes the data. However, due to the limitation of the amount of log data that can be stored in the radiation imaging apparatus, the log at the time to be confirmed may be overwritten and lost. In addition, there is a possibility that log acquisition may be forgotten due to a service person forgetting work. In this way, if the log disappears due to memory capacity limitations, forgetting to acquire the log, etc., it becomes difficult to confirm what kind of abnormality has occurred in the radiation imaging apparatus, and recovery from the abnormal state in the radiation imaging apparatus Takes time.

Therefore, it is desired to reduce the occurrence of loss of logs generated in the radiation imaging apparatus.

A radiation imaging system according to an aspect of the present invention has the following configuration. That is,
A radiation imaging system comprising communication means for providing a communication connection between a radiation imaging device and an imaging control device,
The radiation imaging apparatus includes:
An image transmission means for transmitting a radiation image obtained by imaging to the imaging control device via a communication connection provided by the communication means;
Log generating means for generating a log in the radiation imaging apparatus and storing the log in a log storage unit;
Log transmission for transmitting the log stored in the log storage unit to the imaging control device via a communication connection provided by the communication unit in response to occurrence of a predetermined event in which log update by the log generation unit occurs Means, and
The imaging control device includes:
Receiving means for receiving the radiation image and the log;
Storage means for storing the radiation image received by the receiving means and the log.

According to the present invention, it is possible to reduce the disappearance of the log generated in the radiation imaging apparatus.

Other features and advantages of the present invention will become apparent from the following description with reference to the accompanying drawings.

FIG. 1 is a block diagram illustrating a configuration example of a radiation imaging system according to the first embodiment. FIG. 2 is a diagram illustrating a data configuration example of a log. FIG. 3 is a diagram for explaining changes in log data when a log is updated. FIG. 4 is a flowchart showing processing of the radiation imaging system according to the first embodiment. FIG. 5 is a sequence diagram showing a communication operation of the radiation imaging system according to the first embodiment. FIG. 6 is a diagram illustrating a log combination example. FIG. 7 is a block diagram illustrating a configuration example of a radiation imaging system according to the second embodiment. FIG. 8 is a flowchart showing processing of the radiation imaging system according to the second embodiment. FIG. 9 is a diagram for explaining processing for reflecting the number of times of imaging to a log and an image. FIG. 10 is a block diagram illustrating a configuration example of a radiation imaging system according to the third embodiment. FIG. 11 is a flowchart showing processing of the radiation imaging system according to the third embodiment. FIG. 12A is a diagram for explaining update part extraction processing in a log. FIG. 12B is a flowchart illustrating an update part extraction process in a log. FIG. 13 is a state transition diagram of the radiation imaging apparatus according to the fourth embodiment. FIG. 14 is a block diagram illustrating a configuration example of a radiation imaging system according to the fifth embodiment. FIG. 15A is a flowchart showing processing of the radiation imaging system according to the fifth embodiment. FIG. 15B is a flowchart showing processing of the radiation imaging system according to the fifth embodiment. FIG. 15C is a flowchart illustrating processing of the radiation imaging system according to the fifth embodiment.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

<First Embodiment>
FIG. 1 is a diagram illustrating a function and a configuration example of a radiation imaging system in the first embodiment. In the radiation imaging system, the radiation generator 103 drives the radiation source 120 to generate radiation from the radiation source 120. The radiation imaging apparatus 101 includes a flat panel detector (FPD 121) for radiation detection, and generates a radiation image based on the radiation emitted from the radiation source 120. The radiation imaging apparatus 101 transmits a radiation image and a log to the imaging control apparatus 102 that is an external apparatus. The imaging control apparatus 102 communicates with the radiation imaging apparatus 101 as an external apparatus, and acquires a radiation image and a log. Here, the FPD 121 includes a pixel array in which a plurality of pixels including conversion elements that convert radiation into electric charge are arranged in a two-dimensional matrix, and outputs an electric signal corresponding to the electric charge from the pixel array. A radiographic image is generated based on the electrical signal. As the conversion element that converts radiation into electric charge, an indirect conversion element that includes a scintillator that converts radiation into light and a photoelectric conversion element that converts light into electric charge can be used.

In the radiation imaging apparatus 101, the communication unit 104 performs wireless communication with the imaging control apparatus 102. The image generation unit 105 generates a radiation image based on the radiation detection signal from the FPD 121. The log generation unit 106 generates a log of the radiation imaging apparatus 101 and stores it in the log storage unit 107. The image storage unit 108 stores the radiation image generated by the image generation unit 105. The transmission control unit 109 performs control for transmitting the radiographic image stored in the image storage unit 108 and the log stored in the log storage unit 107 to the imaging control apparatus 102. That is, the transmission control unit 109 operates as an image transmission unit that transmits a radiation image obtained by imaging to the imaging control apparatus 102 via a communication connection provided by the communication units 104 and 110 described later. The transmission control unit 109 also operates as a log transmission unit that transmits a log stored in the log storage unit 107 to the imaging control apparatus 102 via a communication connection. In particular, the log transmission unit executes log transmission in response to occurrence of a predetermined event in which log update by the log generation unit 106 occurs. In the first embodiment, a configuration using transmission of a radiation image obtained by execution of imaging as such a predetermined event will be described.

In addition, each part of the above radiation imaging device 101 may be implement | achieved by cooperation with hardware, when CPU not shown performs the predetermined | prescribed program stored in the memory not shown. Note that some or all of the functions realized by the CPU executing a predetermined program may be realized by dedicated hardware.

In the imaging control apparatus 102, the communication unit 110 performs wireless communication with the radiation imaging apparatus 101. The communication unit 104 and the communication unit 110 provide communication connection between the radiation imaging apparatus 101 and the imaging control apparatus 102. The reception processing unit 112 converts the data received by the communication unit 110 into a format for storing in the data storage unit 111. The data storage unit 111 stores the reception data converted by the reception processing unit 112. The data storage unit 111 has a storage capacity sufficient to store a large number of radiation images and logs. The log combining unit 113 combines a plurality of logs received from the same radiation imaging apparatus stored in the data storage unit 111 into one. Each unit of the imaging control apparatus 102 described above can be realized in cooperation with hardware by executing a predetermined program stored in a memory (not shown) by a CPU (not shown). Note that some or all of the functions realized by the CPU executing a predetermined program may be realized by dedicated hardware. The imaging control apparatus 102 can also be realized by an information processing apparatus such as a general-purpose personal computer.

Although FIG. 1 shows a configuration in which there is one radiation imaging device and one imaging control device, one or both of them may have a plurality of configurations. In the case of a configuration in which at least one of the radiation imaging apparatus and the imaging control apparatus is plural, each of the radiation imaging apparatus and the imaging control apparatus has a unique ID in order to specify one unit. By adding this unique ID to an image or log, it is possible to identify which radiation imaging apparatus has acquired the image. For example, the imaging control apparatus 102 can manage the log separately for each radiation imaging apparatus based on the ID included in the received log. The connection when there are a plurality of radiation imaging apparatuses and imaging control apparatuses will be described with reference to FIG.

FIG. 2 is a diagram showing an example of a log data configuration according to the first embodiment. The log 201 is an operation history that is generated by the log generation unit 106 and can be used to read later how the radiation imaging apparatus 101 has operated. The log 201 includes a time stamp 202 indicating the progress of each operation, that is, the time-series order, and operation information 203. One log item is composed of one time stamp and operation information associated therewith. The operation information 203 can describe operation conditions during radiation imaging, information specific to the radiation imaging apparatus, and the like. Examples of the information specific to the radiation imaging apparatus include setting information, a serial number, and a wireless connection address of the radiation imaging apparatus 101. Information recorded in the log 201 is not limited to the information described in the present embodiment.

The information capacity of the log 201 that can be stored in the radiation imaging apparatus 101 is limited by the storage capacity of the log storage unit 107. Therefore, when the log 201 is stored in the entire storage capacity, the log storage unit 107 overwrites the oldest log item with the latest log item in order from the oldest log item of the time stamp 202 in the stored log 201. The log update will be described with reference to FIG.

FIG. 3 shows a change in log when the log items up to n + 1000 are stored in the log storage unit 107 in which the storage capacity is used for all log items up to the n-th time stamp. A log 301 indicates a log in which up to nth log items are recorded. A log 302 indicates a log in which up to n + 1000th log items are recorded.

The log storage unit 107 records log items up to the nth time stamp as in the case of the log 301. Thereafter, when storing log items up to the (n + 1000) time stamp, the log storage unit 107 sequentially overwrites the first log item from the first time stamp to the 1000th log item with new log items. . After all the storage capacity of the log storage unit 107 is used in this way, the log items of the oldest time stamp are overwritten and updated in order.

In the present embodiment, the number to be counted up is used for the time stamp, but the present invention is not limited to this. The time stamp is a numerical value added by the radiation imaging apparatus 101 as long as the same numerical value does not appear twice. For example, the total drive time of the radiation imaging apparatus 101 may be used as the time stamp. Date and time information to be managed may be used. In this embodiment, an example in which a log is updated using a time stamp has been described, but the present invention is not limited to this. For example, it may be updated using a memory address for storing the log. Or you may make it update for every area of the memory which stores a log. The log storage unit 107 has a storage capacity sufficient to ensure that an untransmitted log is not overwritten between the time when the radiation imaging apparatus 101 transmits a log and the time when the next log transmission is performed. To do.

Next, the operation of the radiation imaging system according to the first embodiment will be described. FIG. 4 is a flowchart showing processing of the radiation imaging system according to the first embodiment.

First, the operation of the radiation imaging apparatus 101 will be described. The radiation imaging apparatus 101 starts operation in response to power ON (step S401). Although not shown in FIG. 4, the initial setting of the radiation imaging apparatus 101 and the like are executed in response to power ON. When the initial setting is completed, in step S402, the communication unit 104 wirelessly connects the radiation imaging apparatus 101 and the imaging control apparatus 102. More specifically, the communication unit 104 transmits a connection request for wireless connection. When the communication unit 104 receives a connection permission reply in response to the connection request from the imaging control apparatus 102, the wireless connection is established.

In step S403, the communication unit 104 confirms whether or not a wireless connection with the imaging control apparatus 102 has been established. If the wireless connection has not been established, the process returns to step S402, and the communication unit 104 tries to establish the wireless connection again by the connection request. Steps S402 and S403 are repeatedly executed until a wireless connection with the imaging control apparatus 102 is established. When the establishment of the wireless connection is confirmed, the process proceeds from step S403 to step S404.

In step S404, the transmission control unit 109 performs initial log transmission from the radiation imaging apparatus 101 to the imaging control apparatus 102 using the wireless connection established by the communication unit 104. In the initial log transmission, the transmission control unit 109 generates all logs stored in the log storage unit 107 as transmission data and transmits the transmission data to the imaging control apparatus 102 via a wireless connection. Subsequently, in step S405, the communication unit 104 confirms whether or not the wireless connection between the radiation imaging apparatus 101 and the imaging control apparatus 102 is maintained. If it is determined that the wireless connection is disconnected, the process returns to step S402. On the other hand, when it is confirmed that the wireless connection is maintained, the process proceeds to step S406. In step S406, the transmission control unit 109 waits for radiation imaging to be performed. Steps S405 and S406 are repeated until radiation imaging is performed.

If an imaging instruction is received from the imaging control apparatus 102 while the wireless connection is maintained (YES in step S406), the radiation imaging apparatus 101 executes imaging in step S407. In imaging, the image generation unit 105 generates a radiation image based on the radiation detection signal from the FPD 121 and stores it in the image storage unit 108. In addition, the log storage unit 107 records information regarding the executed imaging and the current time stamp in the log as log items.

Next, in step S408, the transmission control unit 109 performs image transmission. In the image transmission process, the transmission control unit 109 converts the radiation image stored in the image storage unit 108 into image transmission data and transmits the image transmission data to the imaging control apparatus 102. Subsequently, in step S409, the transmission control unit 109 performs log transmission. In log transmission, the transmission control unit 109 converts the log stored in the log storage unit 107 into log transmission data, and transmits the log transmission data to the imaging control apparatus 102. As described above, when image transmission (step S408) and log transmission (step S409) are performed according to the imaging operation, the process returns to step S405.

Next, the operation of the imaging control apparatus 102 will be described. The imaging control apparatus 102 starts operation in response to power ON (step S410). When the imaging control apparatus 102 starts its operation, it first performs initial settings (not shown). After the initial setting, the process proceeds to step S411. In step S411, the communication unit 110 waits for a connection request (step S402) from the communication unit 104 of the radiation imaging apparatus 101, and returns a connection permission to the radiation imaging apparatus 101 when receiving the connection request. Thereby, the wireless connection between the radiation imaging apparatus 101 and the imaging control apparatus 102 is established. Steps S411 and S412 are repeated until the communication unit 110 confirms the establishment of the wireless connection.

If the establishment of the wireless connection is confirmed in step S412, the process proceeds to step S413. In step S413, the reception processing unit 112 receives the initial log transmitted from the radiation imaging apparatus 101. Thus, when the wireless connection between the radiation imaging apparatus 101 and the imaging control apparatus 102 is established, the imaging control apparatus 102 receives all the logs stored in the radiation imaging apparatus 101.

When the reception of the initial log is completed, the imaging control apparatus 102 confirms whether or not the wireless connection with the radiation imaging apparatus 101 is maintained in step S414. If it is confirmed that the wireless connection is maintained (YES in step S414), the imaging control apparatus 102 determines in step S415 whether or not there is a notification of the start of radiation imaging (hereinafter referred to as an imaging instruction). While waiting for the imaging instruction, step S414 and step S415 are repeated. If it is determined in step S414 that the wireless connection is disconnected, the process returns to step S411 and waits for a connection request from the radiation imaging apparatus 101.

If the imaging instruction is confirmed in step S415, the process proceeds to step S416. In step S416, the imaging control apparatus 102 transmits an imaging start instruction to the radiation imaging apparatus 101. When imaging is executed by the radiation imaging apparatus 101, an image and a log are transmitted (steps S408 and S409). In step S417, the imaging control apparatus 102 receives an image transmitted from the radiation imaging apparatus 101. In step S418, the imaging control apparatus 102 receives a log transmitted from the radiation imaging apparatus 101. In step S419, the log combination unit 113 combines the log received in step S413 and the log received in step S418 to generate one log file. Details of the log combination will be described later with reference to FIG.

The operations of the radiation imaging apparatus 101 and the imaging control apparatus 102 in the radiation imaging system of the first embodiment have been described above. Hereinafter, an operation when there are a plurality of radiation imaging apparatuses 101 and imaging control apparatuses 102 will be described with reference to FIG.

FIG. 5 is a sequence diagram showing a communication operation of the radiation imaging system according to the first embodiment. In FIG. 5, the radiation imaging system includes two radiation imaging devices (referred to as RI501 and RI502, respectively) and two imaging control devices (referred to as CU503 and CU504, respectively). Note that the number of radiation imaging devices and imaging control devices is not limited to the illustration, and the number of both may not be the same, or two or more.

The vertical arrows shown in FIG. 5 indicate the passage of time from top to bottom. A horizontal arrow represents communication performed between the radiation imaging apparatus and the imaging control apparatus. Communication is roughly classified into four types, and includes connection communication performed at the time of connection, an imaging instruction sent from the imaging control apparatus to the radiation imaging apparatus, image transmission transmitted by the radiation imaging apparatus after imaging, and log transmission. In FIG. 5, each communication is shown with different line types.

As shown in connection 508 to connection 512 in FIG. 5, connection communication including connection request and connection response exchange and initial log transmission / reception is performed for each wireless connection between the imaging control apparatus and the radiation imaging apparatus. In connection 508 to connection 509 and connection 511 to connection 512, one image transmission and log transmission are performed in one wireless connection, and in connection 510, two image transmissions and log transmission are performed in one wireless connection. Has been done. As shown in connection 510, connection communication is performed only once at the time of connection, and thereafter, image capturing is performed for each image capturing instruction 505, and accordingly, image transmission 506 and log transmission 507 are performed.

In connection 510 to connection 512, connection 511 in which CU 504 connects to another RI 502 occurs between connection 510 and connection 512 in which RI 501 connects to CU 504. In such a case, connection communication is performed for each connection, and the radiation imaging apparatus stores a log for each connection unit. Note that although FIG. 5 illustrates an example in which the imaging control apparatus is connected to only one radiation imaging apparatus one by one, the present invention is not limited to this. The imaging control device may be configured to be connected simultaneously with a plurality of radiation imaging devices and used while switching the radiation imaging devices. In that case, the connection communication may be performed only for the first connection to each radiation imaging apparatus.

Next, the log reception process in step S418 and the log combination process in step S419 will be described with reference to FIG. The log combining unit 113 of the imaging control apparatus 102 includes a log that is stored by excluding a portion that is duplicated between the newly received log and the log stored in the data storage unit 111 from the received log. Join.

When receiving the log from the radiation imaging apparatus 101, the reception processing unit 112 of the imaging control apparatus 102 adds the unique ID of the radiation imaging apparatus 101 to the received log and stores it in the data storage unit 111. The log combining unit 113 confirms whether a log having the same unique ID as the received log is stored in the data storage unit 111. Here, it is assumed that the log 601 and the log 602 have the same unique ID.

When the log combination unit 113 confirms that there are logs 601 and 602 having the same unique ID, it next checks the time stamp of each log. When there is a time stamp part that exists in common in these two logs and a new time stamp part that exists only in the log 602, the new time stamp part that exists only in the log 602 is added to the log 601. A new combined log 603 is generated. In FIG. 6, log items having time stamps of 00001000 to 00010000 are shown as time stamp portions that exist in common in the log 601 and the log 602. In addition, FIG. 6 shows a state in which a log item having a time stamp of the log 602 of 00010001 and later is added to the log 601 and a combined log 603 is generated.

In FIG. 6, the log combination process in the case where the log of the part transmitted last time remains in the log transmitted later (for example, when all the logs in the radiation imaging apparatus 101 are transmitted each time) is described. . When the transmission control unit 109 transmits only the updated portion from the log transmitted last time, the log combining unit 113 transmits the log transmitted to the log having the same unique ID stored in the data storage unit 111. Need only be combined in time stamp order.

Also, since the logs can be combined if the radiation imaging apparatus has the same unique ID, logs having the same unique ID stored in a plurality of imaging control apparatuses can be combined into one. Thereby, the logs of one radiation imaging apparatus stored in a plurality of imaging control apparatuses can be combined into one.

As described above, according to the first embodiment, the imaging control apparatus 102 acquires the log of the radiation imaging apparatus 101 by performing imaging. Therefore, it is possible to save all the logs of the radiation imaging apparatus 101 without depending on the capacity of the log storage unit 107 of the radiation imaging apparatus 101. That is, the radiographic image and the log are transmitted from the radiation imaging apparatus to the imaging control apparatus every time imaging is performed, so that it is possible to prevent the service person from forgetting to acquire the log. As a result, when an abnormality occurs in the radiation imaging apparatus 101, the operation until the abnormality occurs can be easily reproduced, and the analysis of the phenomenon becomes very easy. Further, even in a situation where the radiation imaging apparatus 101 suddenly stops moving or cannot communicate, information from the imaging control apparatus 102 up to the previous imaging can be acquired.

Further, according to the first embodiment, if the log has a unique ID, it can be collected in one place and made into one log even if stored in different imaging control devices. As a result, it is also possible to confirm and reproduce all logs (operation status) from the start of use of one radiation imaging apparatus 101 to the present. This makes it possible to confirm the exact time at which an abnormality has occurred in the radiation imaging apparatus 101 from the log even if the user has overlooked a malfunction, such as an abnormality occurring in the radiation imaging apparatus 101. The cause investigation becomes easy.

In the first embodiment, the wireless connection is shown as the communication connection between the radiation imaging apparatus 101 and the imaging control apparatus 102, but a wired connection may be used. In addition, a common communication connection is used for log transmission / reception and radiographic image transmission / reception, but independent communication connections may be used as shown in the fifth embodiment. In the first embodiment, the log transmission timing is immediately after the transmission of the radiation image, but is not limited thereto. It may be immediately before the transmission of the radiation image or during the transmission of the radiation image. The same applies to the following second to fourth embodiments.

<Second Embodiment>
In the first embodiment, the configuration in which the imaging control apparatus 102 receives and stores the radiation image and the log transmitted from the radiation imaging apparatus 101 has been described. In the second embodiment, a configuration in which the imaging control apparatus 102 can manage a radiation image and a log related to the radiation image in association with each other will be described. In the following, as an example of such a configuration, in order to associate a radiation image with a log, the radiation image and the log item are associated and managed by using the number of times of radiation imaging performed by the radiation imaging apparatus 101 (number of imaging). The configuration will be described.

FIG. 7 is a block diagram illustrating a configuration example of the radiation imaging system according to the second embodiment. In FIG. 7, the same reference numerals are assigned to the same components as those in the first embodiment (FIG. 1). Hereinafter, the configuration and processing of the second embodiment which are mainly different from the first embodiment will be described. The radiation imaging apparatus 101 includes a count unit 701. The counting unit 701 counts the total number of times of imaging of the radiation imaging apparatus 101. The count unit 701 counts up the number of times of imaging every time an imaging instruction is received from the imaging control apparatus 102. The count number recorded in the count unit 701 is not reset. Therefore, the number of times of imaging counted by the counting unit 701 is hereinafter referred to as the total number of imaging times.

When recording the imaging operation history, the log generation unit 106 reads the total imaging count from the counting unit 701 and adds the imaging count to the log item indicating the imaging operation history. On the other hand, when storing the radiographic image acquired by imaging, the image storage unit 108 reads the total number of imaging times from the count unit 701 to the radiographic image, and adds this to the image.

Next, the operation of the radiation imaging system according to the second embodiment will be described with reference to FIG. FIG. 8 is a flowchart showing processing of the radiation imaging system according to the second embodiment. The same processing steps as those in the first embodiment (FIG. 4) are denoted by the same reference numerals. Hereinafter, processing different from the first embodiment will be mainly described.

If an imaging instruction is received from the imaging control apparatus 102 while the wireless connection is maintained (YES in step S406), in step S801, the counting unit 701 counts up the total number of imagings immediately before performing imaging. To do. Subsequently, in step S407, the radiation imaging apparatus 101 executes imaging. In step S <b> 408, the transmission control unit 109 adds the total number of imaging times to the radiographic image stored in the image storage unit 108 and transmits it to the imaging control apparatus 102. In step S409, the transmission control unit 109 transmits the log stored in the log storage unit 107.

An example of the log in the second embodiment is shown in FIG. A case where the total number of imaging operations counted by the counting unit 701 is N will be described as an example. The same reference numerals as those in FIG. 2 are attached to the same configurations as those in the first embodiment (FIG. 2). In the following, parts different from the first embodiment will be mainly described.

In step S407, the log storage unit 107 records the log item 901 at the time of imaging, adding the total number of imaging counted by the counting unit 701 to the operation information. Further, the image storage unit 108 adds the total number of imaging times to the data name 902 of the radiation image 903 acquired by the imaging (N-th imaging). In step S408, the transmission control unit 109 transmits the radiation image 903 to which the total number of imaging has been added to the imaging control apparatus 102. In step S409, the transmission control unit 109 includes a log item 901 to which the total number of imaging has been added. 201 is transmitted to the imaging control apparatus 102.

In this embodiment, the total number of times of imaging is recorded in a form that is added to the operation information of the log item, but the method of recording the total number of times of imaging is not limited to this. For example, the total number of times of imaging may be recorded as a time stamp at the time of imaging, or only the total number of times of imaging may be recorded as operation information.

As described above, according to the second embodiment, since the total number of times of imaging common to the log and the radiographic image is recorded, the radiographic image and the log are linked from the total number of imaging times even if the radiographic image and the log are stored separately. I can do it. This makes it easy to analyze the radiographic image and the log in association with the past, and facilitates reproduction confirmation and analysis.

In addition, since the total number of times of imaging is increased from when the imaging instruction is received until imaging is performed (between steps S406 and S407), the number of times imaging is instructed from the imaging control apparatus 102. I understand. Further, when there is an abnormality in the imaging process, it can be easily determined at which stage of the imaging process the abnormality has occurred. For example, when imaging failed and an image could not be acquired, whether there was a problem at the stage of imaging instruction by the imaging control apparatus 102 or whether there was a problem in the operation of the radiation imaging apparatus 101 after receiving the imaging instruction Easy to judge.

<Third Embodiment>
In the third embodiment, a configuration will be described in which the transmission control unit 109 of the radiation imaging apparatus 101 extracts an updated part of the log and transmits it to the imaging control apparatus 102. A configuration in which the imaging control apparatus 102 stores a new log received following transmission of a radiographic image in association with the radiographic image (package processing) will be described. In the following description, configurations and operations different from those of the first embodiment will be mainly described. FIG. 10 is a block diagram illustrating a configuration example of a radiation imaging system according to the third embodiment. The same components as those in the first embodiment (FIG. 1) are denoted by the same reference numerals. The transmission control unit 109 according to the third embodiment includes a time stamp storage unit 1001 that stores the last time stamp of a log when transmission data is generated from the log.

FIG. 11 is a flowchart showing the operation of the radiation imaging system according to the third embodiment. The same processing steps as those in the first embodiment (FIG. 4) are denoted by the same reference numerals. The transmission control unit 109 reads the last time stamp stored in the time stamp storage unit 1001 in step S1101 before log transmission is executed in step S409. Then, the transmission control unit 109 extracts a log item stored after the last time stamp as an updated part of the log. In step S409, the transmission control unit 109 generates an update part of the log extracted in step S1101 as transmission data, and transmits the transmission data to the imaging control apparatus 102.

In the imaging control apparatus 102, the reception processing unit 112 receives a log from the radiation imaging apparatus 101 in step S418. After receiving the log, in step S1102, the reception processing unit 112 packages the received radiographic image and log together as one imaging data (package processing), and stores the packaged data in the data storage unit 111.

The process (step S1101) of extracting the updated part of the log by the transmission control unit 109 will be further described with reference to FIGS. 12A and 12B. FIG. 12A is a diagram for explaining extraction processing of a log update portion, and FIG. 12B is a flowchart for explaining the processing. In this extraction process, first, in step S1201, the transmission control unit 109 reads a time stamp (00001000 in FIG. 12A) from the time stamp storage unit 1001. Based on this time stamp, the transmission control unit 109 can distinguish between a log that has been transmitted and a log that has not been transmitted, among the logs stored in the radiation imaging apparatus 101. Next, in step S1202, the transmission control unit 109 extracts a log discriminated as not transmitted, and generates transmission data 1206. In FIG. 12A, log items with time stamps 00001001 to 00010000 are extracted as unsent logs, and transmission data 1206 including them is generated. Next, in step S1203, the transmission control unit 109 records the last time stamp (00010000 in FIG. 12A) of the log transmitted this time in the time stamp storage unit 1001.

In the third embodiment, the read method using the time stamp is shown as the read method of the update part, but the update method is not limited to this. For example, the difference between the log transmitted up to the previous time using a memory address or the like and the current log may be transmitted. Alternatively, instead of the time stamp, when transmitting data is generated, an update part is extracted so that a part that has been transmitted so far can be known by leaving a mark that has already been transmitted in the log item to be transmitted. Good. The method of extracting the log update unit is not limited to that described in this embodiment. In the above description, the radiation imaging apparatus 101 extracts and transmits a new part (untransmitted part) of the log. However, as described in the combining process of the first embodiment, the imaging control apparatus 102 newly A new part may be extracted from the received log and used for package processing.

As described above, according to the third embodiment, when there is an abnormality or the like in the image because the image and the information from the previous imaging to the current imaging are stored as a set in the imaging data, The log corresponding to the image can be confirmed immediately. As a result, image analysis becomes very easy and serviceability is improved.

<Fourth embodiment>
In the first to third embodiments, an example has been described in which the predetermined event that causes the log update by the log generation unit 106 is image transmission (a configuration in which log transmission is performed using image transmission as a trigger). The timing for transmitting the log is not limited to this. In the fourth embodiment, when the occurrence of a transition to a specific state is used as a predetermined event that causes a log update by the log generation unit 106, that is, a log is transmitted when a transition to a specific state is performed. Will be described. Hereinafter, differences between the fourth embodiment and the first embodiment will be mainly described.

FIG. 13 is a diagram showing an operation state of the radiation imaging apparatus 101. The state of the radiation imaging apparatus 101 is roughly divided into two. The first state is a normal state 1301, and the second state is an abnormal state 1302. The normal state 1301 includes sub-states of stop 1303, standby 1304, and imaging 1305. The abnormal state 1302 includes sub-states of an abnormality 1307 and an abnormal stop 1306.

In the state of stop 1303, standby 1304, imaging 1305, and abnormality 1307, the log generation unit 106 can operate and can generate a log. A stop 1303 represents a state where the power of the radiation imaging apparatus 101 is OFF. When the power is turned on, the state transitions from the stop 1303 to the standby 1304. A standby 1304 represents a state in which the radiation imaging apparatus 101 is powered on and imaging 1305 cannot be performed. The state transitions from standby 1304 to imaging 1305 according to an instruction from the imaging control apparatus 102. The imaging 1305 is a state in which an image is acquired by irradiation with radiation. In the imaging 1305, when the image acquisition is completed, the acquired image is transmitted to the imaging control apparatus 102. Thereafter, the state transitions from imaging 1305 to standby 1304.

An abnormality 1307 is a state in which the radiation imaging apparatus 101 cannot continue normal operation due to detection of abnormal operation, settings, etc., but the log generation unit 106 is operable, and in some cases, transitions to the normal state 1301 by itself. Is possible. The transition to the abnormal state occurs when an operation or setting that is not normal is detected during the standby 1304, the imaging 1305, or the transition to each state, and it is determined that the normal operation cannot be continued. An abnormal stop 1306 represents a state in which the log generation unit 106 cannot operate and cannot transition to the normal state 1301 due to detection of an operation or setting of the radiation imaging apparatus 101 that is not normal. By turning off the power, the state can be changed from the abnormal stop 1306 to the stop 1303.

In the fourth embodiment, the transmission control unit 109 generates transmission data from the log stored in the log storage unit 107 and transmits the transmission data to the imaging control apparatus 102 when transitioning to the standby 1304, the abnormality 1307, and the normal state 1301. . Thereafter, only the log is transmitted from the radiation imaging apparatus 101 to the imaging control apparatus 102. When the state transition from the stop 1303 to the standby 1304 is made, the transmission control unit 109 performs initial log transmission and transmits all the logs stored in the log storage unit 107 to the imaging control apparatus 102. Further, when the state transition from the imaging 1305 to the standby 1304, the state transition from the abnormality 1307 to the normal state 1301, and the state transition from the normal state 1301 to the abnormality 1307, as described in the third embodiment, Send the updated part from the previous transmission.

In the fourth embodiment, the log is transmitted when a transition to the standby 1304, the abnormality 1307, and the normal state 1301 occurs. However, the log may be transmitted when the state transitions to another state. . In the fourth embodiment, the log transmission range is changed by state transition, but all logs may be transmitted every time. The state in which log transmission is performed and the range of logs to be transmitted are not limited to this embodiment.

As described above, according to the fourth embodiment, when the radiation imaging apparatus 101 starts up normally, when the imaging 1305 is executed normally, when the imaging 1305 is canceled, an abnormality 1307 occurs in the radiation imaging apparatus 101. If you do, a log will be sent. Therefore, whenever there is any operation in the radiation imaging apparatus 101, a log is always transmitted to the imaging control apparatus 102 and remains. Therefore, it becomes very easy to reproduce the movement of the radiation imaging apparatus 101 by looking at the log.

Further, since all logs when an abnormality 1307 other than the abnormal stop 1306 occurs are left, a problem occurring in the radiation imaging apparatus 101 can be grasped. The user can confirm the circumstances until the abnormality 1307 occurs in the radiation imaging apparatus 101, the relationship between the abnormality 1307 and another abnormality 1307, and the like. As a result, it becomes easier to improve the quality of the radiation imaging apparatus 101.

<Fifth Embodiment>
In the fifth embodiment, log update itself is used as a predetermined event in which log update by the log generation unit 106 occurs. Therefore, in the fifth embodiment, the log is transmitted every time the log is updated. Note that in the fifth embodiment, different communication connections are established for image communication and log communication in order to more reliably transmit logs at any time. That is, in the fifth embodiment, a first communication connection for transmitting a radiation image and a second communication connection different from the first communication connection for transmitting a log are established, and the image and log The transmission process can be operated in parallel. Hereinafter, differences of the fifth embodiment from the first embodiment will be mainly described.

FIG. 14 is a block diagram showing a configuration of a radiation imaging system according to the fifth embodiment. In FIG. 14, the same reference numerals are assigned to the same components as those in the first embodiment (FIG. 1). The image communication unit 1401 is a communication unit for transmitting a radiation image to the imaging control apparatus 102. The log communication unit 1402 is a communication unit for transmitting a log to the imaging control apparatus 102. The log transmission control unit 1403 generates log transmission data using the log stored in the log storage unit 107 and transmits the log transmission data using the log communication unit 1402. The image transmission control unit 1404 generates image transmission data using the radiographic image stored in the image storage unit 108 and transmits the image transmission data using the image communication unit 1401. The image transmission control unit 1404 transmits a radiographic image obtained by the imaging after imaging in accordance with an imaging instruction from the imaging control apparatus 102. Further, the log transmission control unit 1403 transmits log data to the imaging control apparatus 102 when an update occurs in the log stored in the log storage unit 107.

In the imaging control apparatus 102, the log communication unit 1406 provides a communication connection for performing log data communication. The image communication unit 1405 provides a communication connection for performing radiographic image communication. The log reception processing unit 1408 converts the log reception data into a form stored in the data storage unit 111. The image reception processing unit 1409 converts the received radiation image data into a form stored in the data storage unit 111.

15A to 15C are flowcharts for explaining the operation of the radiation imaging system according to the fifth embodiment. The same reference numerals as those in FIG. 4 are attached to the same processes as the processing steps of the first embodiment (FIG. 4).

When the radiation imaging apparatus 101 establishes a wireless connection with the imaging control apparatus 102 (YES in step S408), parallel processing is performed in step S1501. When the parallel processing is performed, operations of two processes of an imaging process after step S1502 and a log transmission process after step S1503 are started. The imaging process and the log transmission process are executed independently of each other. The imaging process and log transmission process continue to be executed when the wireless connection is in the connected state. When the wireless connection is not connected, the processing is stopped, the process returns to the wireless connection communication 402, and the wireless connection is executed.

In the imaging process, steps S405 to S408 described in the first embodiment are executed. That is, while the wireless connection by the image communication unit 1401 is connected (during YES in step S405a), the radiation imaging apparatus 101 executes the radiation imaging according to the imaging instruction from the imaging control apparatus 102, and is obtained. The radiation image is transmitted to the imaging control apparatus 102. Generation and transmission of transmission data using a radiation image is performed by the image transmission control unit 1404 using the image communication unit 1401.

In the log transmission process, first, in step S404, the log transmission control unit 1403 executes the initial log transmission only once after wireless connection. Thereafter, while the wireless connection with the imaging control apparatus 102 by the log communication unit 1402 is connected (during YES in step S405b), the log transmission control unit 1403 confirms the occurrence of the log update in step S1504, and then proceeds to step S409. Execute log transmission with. In log transmission, it is preferable to transmit the log of the updated portion of the log stored in the log storage unit 107. It is because it is inefficient to transmit all the logs in the log storage unit 107 every time a log item is added.

On the other hand, the imaging control apparatus 102 performs parallel processing 1505 in step S1505 after establishing a wireless connection with the radiation imaging apparatus 101 (YES in step S412). In the parallel processing, the image reception processing after step S1506 and the log reception processing after step S1507 are executed in parallel. The image reception processing unit 1409 and the log reception processing unit 1408 respectively execute the image reception processing and the log reception processing independently. The image reception process and the log reception process are executed while the wireless connection with the radiation imaging apparatus 101 is in the connected state. When the wireless connection with the radiation imaging apparatus 101 is not connected, the process returns to step S411 and waits for establishment of the wireless connection with the radiation imaging apparatus 101.

In the image reception process, the image reception processing unit 1409 receives a radiation image from the radiation imaging apparatus 101 using the wireless connection established by the image communication unit 1405. The image reception process is executed while the wireless connection established by the image communication unit 1405 is maintained (during YES in step S414a). When the wireless connection is disconnected, the process returns to step S411. In the image reception process, the same processes as in steps S414 to S417 of the first embodiment are executed. On the other hand, in the log reception process, in step S413, the log reception processing unit 1408 uses the log communication unit 1406 to execute initial log reception only once after wireless connection. Thereafter, while the wireless connection with the radiation imaging apparatus 101 is in the connected state (during YES in step S414b), in step S1508, the log reception processing unit 1408 continues to wait for reception of log data. When the log reception processing unit 1408 receives a log from the radiation imaging apparatus 101 via the log communication unit 1406 (steps S1508 and S418), the log combination unit 113 executes log combination processing in step S419.

As described above, according to the fifth embodiment, log transmission is performed each time the radiation imaging apparatus is updated in the log. For this reason, all logs are stored in the imaging control device unless the power of the radiation imaging device is turned off, the communication stops due to an abnormal stop, or the wireless connection is disconnected. As a result, the operation history from the operation start to the operation stop of the radiation imaging apparatus 101 can be confirmed, so that accurate support can be provided even in a remote place.

Note that the first communication connection provided by the image communication units 1401 and 1405 may be faster than the second communication connection provided by the log communication units 1402 and 1406. One or both of the first and second communication connections may be wired connections. In the fifth embodiment, individual communication connections are established for image communication and log communication. However, as described in the first to fourth embodiments, a common communication connection is used for image communication and log communication. May be. In this case, image communication and log communication are performed in a time division manner.

As described above, according to the radiation imaging system of each embodiment, log data is transmitted from the radiation imaging apparatus to the imaging control apparatus in response to the occurrence of a predetermined event, so that it is possible to prevent a service person from forgetting to obtain a log. . Further, if all the operation logs of the radiation imaging apparatus remain, it becomes possible to check the abnormality retroactively. Therefore, even when the time when the user recognizes the abnormality is different from the time when the abnormality actually occurs, the abnormality occurrence time can be accurately specified, and the time for investigating the cause is shortened. In addition, since the past operation log of the radiation imaging apparatus remains, it is possible to track the operation up to the occurrence of an abnormality, so that the phenomenon can be easily reproduced. Furthermore, since the log can be automatically transmitted and stored outside the radiation imaging apparatus, the memory area for storing the log data can be reduced, so that the memory can be effectively used.

<Other embodiments>
The present invention supplies a program that realizes one or more functions of the above-described embodiments to a system or apparatus via a network or a storage medium, and one or more processors in a computer of the system or apparatus read and execute the program This process can be realized. It can also be realized by a circuit (for example, ASIC) that realizes one or more functions.

The present invention is not limited to the above embodiment, and various changes and modifications can be made without departing from the spirit and scope of the present invention. Therefore, in order to make the scope of the present invention public, the following claims are attached.

This application claims priority based on Japanese Patent Application No. 2018-016695 filed on Feb. 1, 2018, the entire contents of which are incorporated herein by reference.

Claims (37)

1. A radiation imaging system comprising communication means for providing a communication connection between a radiation imaging device and an imaging control device,
   The radiation imaging apparatus includes:
   An image transmission means for transmitting a radiation image obtained by imaging to the imaging control device via a communication connection provided by the communication means;
   Log generating means for generating a log in the radiation imaging apparatus and storing the log in a log storage unit;
   Log transmission for transmitting the log stored in the log storage unit to the imaging control device via a communication connection provided by the communication unit in response to occurrence of a predetermined event in which log update by the log generation unit occurs Means, and
   The imaging control device includes:
   Receiving means for receiving the radiation image and the log;
   A radiation imaging system comprising: the radiation image received by the receiving means; and storage means for storing the log.
2. The radiation imaging system according to claim 1, wherein the predetermined event is that imaging has been executed or a radiation image obtained by execution of imaging has been transmitted.
3. The radiation imaging apparatus further includes a counting unit that counts the number of times of imaging,
   The log transmitted by the log transmission unit and the radiographic image transmitted by the image transmission unit include information indicating the number of times of imaging,
   The radiation storage system according to claim 1, wherein the storage unit manages the radiation image and the log in association with each other using the number of imaging.
4. 4. The radiation imaging system according to claim 3, wherein the counting unit updates the number of imaging after receiving an imaging instruction and before performing imaging according to the imaging instruction.
5. In the imaging control apparatus, a combination that combines a log received by the receiving unit and a log stored in the storage unit by excluding a portion overlapping with the log stored in the received log. The radiation imaging system according to claim 1, further comprising means.
6. The log items constituting the log include a time stamp indicating time-series order and operation information,
   6. The radiation imaging system according to claim 5, wherein the combining unit identifies the overlapping portion with reference to the time stamp.
7. The log transmission means extracts and transmits an untransmitted log when transmitting a log in response to transmission of a radiation image,
   5. The radiation imaging system according to claim 1, wherein the imaging control apparatus stores the received radiation image and the received log in association with each other.
8. The radiation imaging system according to any one of claims 1 to 7, wherein the predetermined event is a transition to a specific state of the radiation imaging apparatus.
9. The transition to the specific state is at least one of a transition to a standby state in which an imaging instruction can be accepted, a transition from an abnormal state to a normal state, and a transition from a normal state to an abnormal state. The radiation imaging system according to claim 8.
10. The radiation imaging system according to any one of claims 1 to 9, wherein the predetermined event is occurrence of update of the log by the log generation unit.
11. The radiation imaging system according to any one of claims 1 to 10, wherein the image transmission unit and the log transmission unit use a common communication connection.
12. The communication means establishes a first communication connection for transmitting the radiation image and a second communication connection different from the first communication connection for transmitting the log. The radiation imaging system according to any one of claims 1 to 11.
13. The radiation imaging system according to claim 12, wherein the first communication connection is a higher-speed communication than the second communication connection.
14. The log includes an ID unique to the radiation imaging apparatus,
    The radiation according to any one of claims 1 to 13, wherein the storage unit manages the log separately for each radiation imaging apparatus based on an ID included in the log received by the reception unit. Imaging system.
15. A radiation imaging apparatus that captures a radiation image based on radiation emitted from a radiation generation apparatus,
    A communication means for providing a communication connection with an external device;
    Log generation means for generating a log and storing it in a log storage unit;
    An image transmitting means for transmitting a radiation image acquired by imaging using a communication connection provided by the communication means;
    Log transmission means for transmitting a log stored in the log storage unit to the external device via a communication connection provided by the communication means in response to occurrence of a predetermined event accompanied by log update by the log generation means; A radiation imaging apparatus comprising:
16. 16. The radiation imaging apparatus according to claim 15, wherein the predetermined event is that imaging has been executed or a radiation image obtained by execution of imaging has been transmitted.
17. 17. The radiation imaging apparatus according to claim 16, wherein the log transmission unit transmits the log subsequent to the transmission of the radiation image by the image transmission unit.
18. It further comprises a counting means for counting the execution of the imaging and obtaining the number of imaging,
    The log generation unit adds the number of times of imaging to a log item related to the imaging,
    18. The radiation imaging apparatus according to claim 16, wherein the image transmission unit transmits the radiographic image data obtained by the imaging with the number of imaging times added.
19. 19. The radiation imaging apparatus according to claim 18, wherein the counting unit updates the number of imaging after receiving an imaging instruction and before performing imaging according to the imaging instruction.
20. The log transmission unit extracts and transmits an untransmitted log from a log stored in the log storage unit when transmitting a log in response to transmission of a radiation image. The radiation imaging apparatus described in 1.
21. 21. The radiation imaging apparatus according to any one of claims 15 to 20, wherein the predetermined event is a transition to a specific state of the radiation imaging apparatus.
22. The transition to the specific state is at least one of a transition to a standby state in which an imaging instruction can be accepted, a transition from an abnormal state to a normal state, and a transition from a normal state to an abnormal state. The radiation imaging apparatus according to claim 21.
23. 23. The radiation imaging apparatus according to claim 15, wherein the predetermined event is occurrence of update of the log by the log generation unit.
24. The communication means establishes a first communication connection for transmitting the radiation image and a second communication connection different from the first communication connection for transmitting the log. The radiation imaging apparatus according to any one of claims 15 to 23.
25. 25. The radiation imaging apparatus according to claim 24, wherein the first communication connection is a higher-speed communication than the second communication connection.
26. 26. The log transmission unit according to claim 15, wherein the log transmission unit transmits all the logs stored in the log storage unit in response to establishment of a communication connection provided by the communication unit. The radiation imaging apparatus described in 1.
27. An imaging control device that acquires a radiation image from a radiation imaging device,
    Communication means for providing a communication connection with the radiation imaging apparatus;
    Image receiving means for receiving a radiation image from the radiation imaging apparatus via a communication connection provided by the communication means;
    Log receiving means for receiving a log from the radiation imaging apparatus via a communication connection provided by the communication means;
    An imaging control apparatus comprising: the radiographic image received by the image receiving unit; and a storage unit that stores the log received by the log receiving unit.
28. The apparatus further comprises combining means for combining the stored log by excluding the overlapping part between the log received by the log receiving means and the log stored in the storage means from the received log. The imaging control device according to claim 27.
29. The log items constituting the log include a time stamp indicating time-series order and operation information,
    29. The imaging control apparatus according to claim 28, wherein the combining unit identifies the overlapping portion with reference to the time stamp.
30. The log includes an ID unique to the radiation imaging apparatus,
    30. The management device according to any one of claims 27 to 29, further comprising a management unit that manages the log separately for each radiation imaging apparatus based on an ID included in the log received by the log reception unit. Imaging control device.
31. Radiation image data received by the image receiving means includes the number of imaging times counted by the radiation imaging device,
    The log received by the log receiving means includes a log item including the number of times of imaging,
    31. The imaging control apparatus according to claim 27, wherein the storage unit manages the radiographic image and the log item in association with each other using the imaging count.
32. 28. The storage means stores the radiographic image received by the image receiving means in association with the new log received by the log receiving means following reception of the radiographic image. 31. The imaging control device according to any one of 31.
33. 33. The communication means establishes a first communication connection for receiving the radiation image and a second communication connection different from the first communication connection for receiving the log. The imaging control device according to any one of the above.
34. 34. The imaging control apparatus according to claim 33, wherein the first communication connection is a higher-speed communication than the second communication connection.
35. A method for controlling a radiation imaging system comprising a communication means for providing a communication connection between a radiation imaging apparatus and an imaging control apparatus,
    An image transmission step in which the radiation imaging apparatus transmits a radiation image obtained by imaging to the imaging control apparatus via a communication connection provided by the communication unit;
    A log generation step in which the radiation imaging apparatus generates a log in the radiation imaging apparatus and stores the log in a log storage unit;
    The radiation imaging apparatus is stored in the log storage unit to the imaging control apparatus via a communication connection provided by the communication unit in response to the occurrence of a predetermined event in which a log update by the log generation step occurs. A log sending process for sending logs;
    A receiving step in which the imaging control device receives the radiation image and the log;
    A radiation imaging system control method, wherein the radiation imaging apparatus includes a storage step of storing the radiation image received in the reception step and the log.
36. A method for controlling a radiation imaging apparatus that captures a radiation image based on radiation emitted from a radiation generator,
    A communication process for providing a communication connection with an external device;
    A log generation step of generating a log and storing the log in a log storage unit;
    An image transmission step of transmitting a radiation image acquired by imaging using the communication connection provided in the communication step;
    A log transmission step of transmitting a log stored in the log storage unit to the external device via a communication connection provided in the communication step in response to occurrence of a predetermined event accompanied by a log update in the log generation step And a method of controlling the radiation imaging apparatus.
37. A control method of an imaging control device that acquires a radiation image from a radiation imaging device,
    Providing a communication connection with the radiation imaging device;
    An image receiving step of receiving a radiation image from the radiation imaging apparatus via the communication connection provided in the communication step;
    A log receiving step of receiving a log from the radiation imaging apparatus via the communication connection provided in the communication step;
    An imaging control apparatus control method comprising: the radiation image received in the image reception step; and a storage step of storing the log received in the log reception step.

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