JP4878257B2 - X-ray detector selection method, program, and X-ray detector selection device - Google Patents

Description

  The present invention relates to a detector management method and management apparatus for an X-ray imaging apparatus that visualizes X-rays using an X-ray detector.

  In recent X-ray imaging apparatuses for medical use, digital X-ray imaging apparatuses using various methods have become widespread with the advance of digital technology. For example, a computed radio that generates a latent image of an X-ray intensity distribution on a photostimulable phosphor, excites the latent image by laser scanning the photostimulable phosphor, and reads the generated fluorescence with a photomultiplier tube. There are graphic (CR) devices.

In addition, a radiation plane X-ray detector in which a phosphor and a large area amorphous silicon (a-Si) sensor are in close contact, a so-called flat panel detector (FPD), is used to directly digitize a radiation image without using an optical system or the like. A digital X-ray imaging apparatus has been put into practical use. In addition, direct photoelectric conversion of radiation using amorphous selenium (a-Se), gallium arsenide (GaAs), tellurium cadmium (CdTe), lead iodide (PbI ₂ ), mercury iodide (HgI ₂ ), etc. FPDs that convert to electrons have also been put into practical use.

  In recent years, an apparatus called a portable cassette or an electronic cassette in which only the X-ray detector unit is portable has become widespread, and it has become possible to flexibly handle all types of imaging.

  Here, in the digital X-ray imaging apparatus as described above, various characteristics of the X-ray detector are different depending on the method and the like, and the image quality of the output image is also different. In addition, even with an extremely precise manufacturing process, it is difficult to manufacture an X-ray detector having completely the same characteristics, and even with the same type of X-ray detector, there is a considerable difference in image quality. Furthermore, the performance degradation of the X-ray detector due to changes over time is inevitable, and it is difficult to maintain the same image quality over a long period of time, and image quality fluctuations may occur.

  Various characteristics of the X-ray detector include spatial resolution, contrast, noise, dynamic range, linearity, uniformity, detection efficiency, sensitivity, and the like. These use various evaluation indices such as MTF (modulation transfer function), NPS (noise power spectrum), DQE (detective quantum efficiency), SNR (signal-to-noise ratio), etc., so that unified image quality evaluation can be performed. It becomes possible.

  Further, image quality fluctuations of the X-ray detector are required to be strictly managed by periodically performing image quality evaluation as described above. Such quality control (QC) is called constancy testing, and the evaluation items are defined by IEC (International Electro technical Commission), JIS (Japanese Industrial Standards) and the like.

  The measurement is usually performed by photographing a QC phantom. This QC phantom arranges multiple types of image quality measurement patterns composed of synthetic resin or metal with known X-ray absorption rate in a reference material made of synthetic resin such as acrylic resin or urethane resin. Designed to measure evaluation items. The configuration of such a QC phantom is disclosed in Patent Document 1.

JP 2001-17417 A

  By the way, the image quality characteristics of the X-ray detector change with time, but the degree of image quality deterioration varies depending on the method, frequency of use, incident dose of the X-ray detector, etc., and the invariance test is strictly performed. In some cases, the test frequency (interval) varies. Accordingly, there is a problem that the user needs to grasp all the test times according to each X-ray detector, and the quality control of the X-ray detector becomes complicated.

  Further, in the digital X-ray imaging apparatus, the required specifications for the image quality are different for each inspection item. For example, spatial resolution, contrast, etc. are emphasized in examinations for observing detailed information such as trabecular bones of the body, and noise characteristics, sensitivity, etc. are emphasized in examinations for low-dose imaging. In order for the user to obtain the best image quality, it is necessary to select an optimal one from a plurality of X-ray detectors for each examination. In particular, even in the same type of X-ray detector as described above, the image quality characteristics are not a little different, and the image quality characteristics of the X-ray detector change over time. Therefore, the user selects the best X-ray detector for each inspection item. It is difficult to select manually.

  Therefore, the object of the present invention is to solve the above-mentioned problems, manage the quality status of a plurality of X-ray detectors, and perform quality control and optimum imaging reflecting the X-ray detector method and degradation status. An object of the present invention is to provide a detector management method and management apparatus for an X-ray imaging apparatus.

An X-ray detector selection method according to one embodiment of the present invention includes a storage step of storing a result of an invariance test for each of a plurality of X-ray detectors in a storage unit, and each of the plurality of X-ray detectors. The acquisition unit obtains the required specifications relating to the quality acquisition process in which the acquisition unit acquires the size information and the result of the invariance test as quality information, and the size and quality of the X-ray detector corresponding to the imaging information used for imaging. A specification acquisition step to be acquired, and a selection step in which a selection unit selects at least one X-ray detector from the plurality of X-ray detectors based on the acquired quality information and the required specification.

An X-ray detector selection device according to an aspect of the present invention includes a storage unit that stores results of constancy tests regarding repetitive quality, size information about each of a plurality of X-ray detectors, and the latest information about the non-continuity. Quality acquisition means for acquiring quality information indicating the result of the denaturation test, specification acquisition means for acquiring required specifications regarding the size and quality of the X-ray detector corresponding to imaging information used for imaging, and the acquired And selecting means for selecting at least one X-ray detector from the plurality of X-ray detectors based on quality information and the required specifications.

According to the present invention, quality information of a plurality of X-ray detectors can be managed, and a detector can be selected and photographed based on the characteristics and deterioration state of the X-ray detectors, so that good image quality can be obtained. Can do.

The present invention will be described in detail based on the embodiments shown in the drawings.
FIG. 1 is a block circuit configuration diagram of an X-ray imaging system according to the first embodiment. The detector management apparatus 10 is an apparatus that manages the quality status of the X-ray imaging apparatuses 20 and 30. The detector management apparatus 10 includes an information transmission circuit 11, an information reception circuit 12, a quality information acquisition circuit 13, a photographing information acquisition circuit 14, a quality information update circuit 15, and a quality information display 16.

  The X-ray imaging apparatus 20 includes an information transmission circuit 21, an information reception circuit 22, an imaging control circuit 23, a display 24, an operation panel 25, an X-ray generation circuit 26, and an X-ray detector 27. Similarly, the X-ray imaging apparatus 30 includes an information transmission circuit 31, an information reception circuit 32, an imaging control circuit 33, a display 34, an operation panel 35, an X-ray generation circuit 36, and an X-ray detector 37.

  Here, the detector management apparatus 10 is connected to the X-ray imaging apparatuses 20 and 30 via the network 40, and is configured to be able to exchange information with each other. Further, the detection order information is supplied via the network 40.

  In the first embodiment, a case where two X-ray imaging apparatuses 20 and 30 are connected to one detector management apparatus 10 will be described in order to simplify the description. Needless to say, it may be connected to an X-ray imaging apparatus of more than one table. In addition, the X-ray imaging apparatuses 20 and 30 are each configured to include one X-ray detector 27 and 37, but may include a plurality of X-ray detectors.

  In such a configuration, the X-ray imaging apparatus 20 is connected to the network via the information transmission circuit 21 and the information reception circuit 22, and receives examination order information requested by the information reception circuit 22 from an external device (not shown). . The examination order information includes a plurality of examination information and imaging information for each recipient. Examples of examination information include examination status, reception number, recipient name, recipient ID, recipient's date of birth, recipient. There are genders. As an example of the imaging information, there are imaging conditions such as imaging date and time, imaging site, imaging direction, tube voltage, tube current, and irradiation time.

  The examination order information acquired in the information receiving circuit 22 is displayed on the display 24 arranged on the operation panel 25 shown in FIG. 2 so that the operator can confirm it. The X-ray imaging apparatus 20 detects the selection of the examinee to perform the examination by the operator from the displayed examination order information. Furthermore, the selection is confirmed by detecting the selection of the examination start button 25a.

  FIG. 3 is an example of imaging information of the selected examinee displayed on the display 24. The X-ray imaging apparatus 20 detects the selection of the examinee who will perform imaging from the displayed imaging information via the operation panel 25. Then, shooting is determined by detecting selection of the shooting start button 25b by the operator. A shooting instruction signal generated in response to detection of selection of the shooting start button 25 b is transmitted to the shooting control circuit 23. The imaging control circuit 23 receives an imaging instruction and controls the X-ray generation circuit 26 and the X-ray detector 27 to execute X-ray imaging.

  In X-ray imaging, the X-ray generation circuit 26 first radiates an X-ray beam to the subject. The X-ray beam radiated from the X-ray generation circuit 26 passes through the subject while being attenuated, reaches the X-ray detector 27, and the X-ray image signal converted into an electrical signal by the X-ray detector 27 is obtained. can get.

  FIG. 4 is a flowchart of the processing procedure of the detector management apparatus 10. First, in step S <b> 1, the information transmission circuit 11 waits for an imaging end notification from the X-ray imaging apparatus 20. When the X-ray imaging is completed and the information transmission circuit 11 receives an end notification, the quality information acquisition circuit 13 acquires the quality information of the X-ray detector 27 used for imaging in the next step S2. The acquisition method is not particularly limited. For example, an ID number is assigned to the X-ray detector 27 in advance, and quality information up to the previous imaging corresponding to the ID number of the X-ray detector 27 used for imaging is used. Can be obtained from an external database or the like. The ID number may be stored in the built-in memory of the X-ray detector 27 and acquired from the built-in memory at the time of imaging. Further, a barcode holding information related to the ID number may be pasted on the X-ray detector 27 and read manually at the time of imaging.

  Here, the quality information indicates information related to the quality of the X-ray detector, and is, for example, information listed below.

(1) The start date of use of the X-ray detector and the date on which the constancy test was performed.
(2) Information on the number of times of photographing (total number of times of photographing, number of times of photographing in the past few days, number of times of photographing since the last constancy test)
(3) Information on the usage period of the X-ray detector (number of days since the start of use, number of days since the start of use, number of days since the last constancy test, number of days since the last constancy test ).
(4) Information related to shooting frequency (average number of shootings per day, average number of shootings per year).
(5) Information serving as an index of imaging dose (total irradiation dose, total incident dose, total irradiation dose from the last constancy test, total incident dose from the last constancy test).
(6) The last update date and time of quality information.

  The information up to the previous shooting is already recorded in an external database or the like, and the quality information is acquired. In addition, regarding the day on which the constancy test was performed, an operator may register in advance for each X-ray detector.

  In step S3, the shooting information acquisition circuit 14 acquires shooting information used for shooting. Although the acquisition method is not particularly limited, for example, the shooting information may be transmitted to the information transmission circuit 11 together with the end notification and the shooting information may be acquired from the information reception circuit 12. Note that shooting information up to the previous shooting may be recorded in advance in an external database or the like, and may be acquired including past shooting information.

  Here, the imaging information includes, for example, imaging date / time, imaging region, imaging direction, imaging conditions (tube voltage, tube current, irradiation time) and the like. Further, the radiographing information includes information obtained from the radiographed X-ray image signal, and the radiographed X-ray image such as the average value, maximum value, minimum value, and standard deviation of ROI (region of interest) of the radiographed X-ray image. It may be the signal itself.

  Next, in step S4, the quality information update circuit 15 updates the quality information of the X-ray detector 27 acquired by the quality information acquisition circuit 13 based on the imaging information acquired by the imaging information acquisition circuit 14. For example, the number of times of photographing may be obtained by acquiring information related to the number of times of photographing from the acquired quality information and incrementing the number of times. The elapsed days of the X-ray detector 27 can be obtained from the difference between the imaging date acquired from the imaging information and the use start date of the X-ray detector 27 or the date on which the constancy test was performed. Further, the number of working days may be incremented if the last update date of the quality information is different from the shooting date acquired from the shooting information. Furthermore, the average number of imaging can be obtained by dividing the updated number of working days of the X-ray detector 27 and the number of imaging.

  Further, the irradiation dose that serves as an index of the imaging dose can be estimated from information on the tube voltage and tube current of the X-ray tube or the irradiation time. In particular, it has been experimentally confirmed that the irradiation dose is approximately proportional to the mAs value calculated from the tube current (mA) and the irradiation time (s), and the irradiation dose is obtained by calculating the mAs value. be able to.

  Since the output value of the X-ray image is proportional to the incident dose, the incident dose of the X-ray detector 27 can be calculated by using the output value of the X-ray image. As a matter of course, since the incident dose is not uniform over the entire surface of the X-ray detector 27, for example, an average value or maximum value of ROI obtained from imaging information may be used as an index of the incident dose. Information on an automatic dose setting mechanism called AEC (Auto Exposure Control) or phototimer can also be used. Thus, the quality information can be updated by adding the calculated imaging dose index value to the previous information.

  Next, in step S5, the quality information updated by the quality information update circuit 15 is displayed on the quality information display 16. Although the display method is not particularly limited, a quality information list is displayed for each X-ray detector as shown in FIG. 5, and the quality information of the X-ray detector corresponding to each update of the quality information is displayed. Update it.

  In FIG. 5, (a) quality information from the start of use and (b) quality information from the date when the last constancy test was performed are displayed for each X-ray detector. Here, regarding the display method, the user may customize display items. Further, even when information is transmitted from the quality information display 16 to the X-ray imaging apparatus including the X-ray detector whose quality information is updated via the information transmission circuit 11, the quality information is displayed on the X-ray imaging apparatus side. Good.

  According to the above-described embodiment, the quality information of a plurality of X-ray detectors is managed, and the latest quality information is displayed for each X-ray detector, so that the operator can easily grasp the quality status. it can.

  FIG. 6 shows an X-ray imaging system according to the second embodiment. The detector management apparatus 10 ′ is provided with a notification circuit 17 that notifies the detector management apparatus 10 of FIG. 1 of the necessity of a quality test, and information that includes the information transmission circuit 11 and the information reception circuit 12 are integrated. A transmission / reception circuit 18 is provided. In the X-ray imaging apparatuses 20 ′ and 30 ′, information transmission / reception circuits 28 and 38 are provided in place of the information transmission circuits 21 and 31 and the information reception circuits 22 and 32, respectively.

  FIG. 7 is a flowchart of a processing procedure performed by the detector management apparatus 10 ′. Steps for executing the same processes as those in the flowchart of FIG. 4 are given the same reference numerals. In step S <b> 11, the notification circuit 17 extracts a threshold (TH) serving as a determination reference from the quality information update circuit 15 and a determination value corresponding to the threshold. The threshold value used as a criterion for determination is a reference value for determining whether or not to perform the constancy test. For example, the number of days that have passed since the last constancy test was performed, the number of working days, and the number of shootings. The upper limit of the total irradiation dose and the total incident dose may be set. As the determination value corresponding to the threshold value, information corresponding to the item set as the determination criterion may be extracted from the information updated by the quality information update circuit 15.

  Here, what quality information is used as a reference value for determination may be set arbitrarily by the user. Further, the upper limit value may be obtained by recording in advance in an external database or the like and reading out the data depending on how often the user wants to execute the invariance test. Note that one or more determination reference values may be set.

  In step S12, the notification circuit 17 compares the determination value with a threshold value (TH) serving as a reference value. Here, since the reference value to be determined is an upper limit value until the next constancy test is performed, if the determination value is larger than the threshold value, it is determined that the constancy test is necessary. Conversely, if the determination value is less than or equal to the threshold value, it is determined that the constancy test is unnecessary. When a plurality of reference values for determination are set, if any of the determination values exceeds the reference value, it may be determined that the constancy test is necessary.

  Next, in step S13, the notification circuit 17 notifies the necessity of the constancy test. The notification method is not particularly limited. For example, if a test necessity item is added to the quality information list displayed on the quality information display 16 as shown in FIG. 8 and necessary / unnecessary is displayed for each X-ray detector. Good. Further, the notification circuit 17 may transmit information to the X-ray imaging apparatus provided with each X-ray detector and notify the X-ray imaging apparatus about the necessity / unnecessity of the constancy test via the information transmission circuit 11. .

  According to the above-described embodiment, the quality information of a plurality of X-ray detectors is managed, the latest quality information for each X-ray detector is displayed, and the quality information of each X-ray detector is not suitable depending on the system and the deterioration status. By informing the time of the denaturation test, there is an effect that strict quality control can be performed.

  FIG. 9 shows an imaging system according to the third embodiment having a plurality of X-ray imaging apparatuses and a detector management apparatus 10 ″ for managing them. This detector management apparatus 10 ″ is the second embodiment. Is provided with an X-ray detector selection circuit 19 for selecting an X-ray detector based on the quality information.

  In the third embodiment, the X-ray detector to be imaged is detected by the detector management device 10 based on the imaging information included in the examination order information received from an external device (not shown) and the quality information of each X-ray detector. In other words, imaging is performed by transmitting the examination order information from the detector management apparatus 10 "to the X-ray imaging apparatuses 20 'and 30' having the selected X-ray detector. .

  10 is a flowchart of a processing procedure performed by the detector management apparatus 10 ″, and steps for executing the same processes as those in the flowchart of FIG. 7 are given the same reference numerals. First, in step S21 of FIG. When the information transmission / reception circuit 18 waits for the inspection order information and the inspection order information is received, the imaging information acquisition circuit 14 acquires the imaging information from the inspection order in step S22.

  In the next step S23, the quality information acquisition circuit 13 acquires quality information related to the quality of all X-ray detectors. In addition to the above-mentioned quality information, the quality information includes the results of previous invariance tests (spatial resolution, contrast, noise, dynamic range, linearity, uniformity, detection efficiency, sensitivity, etc.) of each X-ray detector, X-ray detection Acquire basic characteristics (pixel pitch, sensor size, etc.). The result of the constancy test may be recorded in an external database or the like at the time of the test, and the data may be read and acquired. Also, basic characteristics of the X-ray detector may be recorded in an external database or the like when the X-ray detector is purchased, and the data may be read out and acquired.

  Next, in step S24, the X-ray detector selection circuit 19 selects an X-ray detector suitable for imaging based on the imaging information acquired from the imaging information acquisition circuit 14 and the quality information acquired from the quality information acquisition circuit 13. . For example, the minimum required specifications of quality information such as spatial resolution, contrast, noise, dynamic range, linearity, uniformity, detection efficiency, sensitivity, etc. are set in advance for each imaging region. Here, the minimum required specification corresponding to the part information acquired by the imaging information may be read out and an X-ray detector satisfying the minimum required specification may be selected.

  If there are a plurality of X-ray detectors that satisfy the minimum required specifications, the quality information that is most important is set in advance. For example, the X-ray detector having the highest contrast may be selected from among the X-ray detectors satisfying the minimum required specifications while setting the focus on the contrast. Further, in order to prevent the allocation of X-ray detectors from being biased, for example, when a plurality of X-ray detectors are selected, the X-ray detector whose quality information is most recently updated, that is, since the last image was taken. The X-ray detector that has passed the most time may be selected. If there is no X-ray detector satisfying the minimum required specifications, the X-ray detector having the best quality information that is most important may be selected.

  Note that the selection method is not limited to this. For example, the X-ray detector may be selected according to the imaging conditions. Further, a rule-based method for obtaining a final candidate according to a certain rule or a method such as selecting an X-ray detector using a neural network may be used.

  Next, an inspection order is transmitted to, for example, the X-ray imaging apparatus 20 ′ including the X-ray detector selected by the information transmitting / receiving circuit 18 in step S 25. The X-ray imaging apparatus 20 ′ that has received the inspection order performs imaging according to the inspection order.

  According to the above embodiment, quality information of a plurality of X-ray detectors can be managed, and an optimal X-ray detector can be selected and imaged based on the X-ray detector system and the deterioration state. There is an effect of always obtaining good image quality.

  The preferred embodiments of the present invention have been described above, but the present invention is not limited to these embodiments, and various modifications and changes can be made within the scope of the gist thereof.

  In addition, a case is also achieved in which a software program that realizes the functions of the above-described embodiments is also achieved by directly or remotely supplying a system or apparatus to the program or reading and executing the supplied program code.

  Therefore, since the functions of the present invention are implemented by computer, the program code installed in the computer also implements the present invention. That is, the computer program itself for realizing the functional processing of the present invention is also included.

  As a recording medium for supplying the program, for example, a floppy (registered trademark) disk, hard disk, optical disk, magneto-optical disk, MO, CD-ROM, CD-R, CD-RW, magnetic tape, nonvolatile memory card, There are ROM and DVD.

  In addition, the program can be supplied by connecting to a homepage on the Internet using a browser of a client computer and downloading the computer program of the present invention or a compressed file including an automatic installation function. It can also be realized by dividing the program code constituting the program of the present invention into a plurality of files and downloading each file from a different homepage. That is, a WWW server that allows a plurality of users to download a program file for realizing the functional processing of the present invention on a computer is also included in the present invention.

  In addition, the program of the present invention is encrypted, stored in a storage medium such as a CD-ROM, distributed to the users, and key information for decrypting the encryption from a homepage via the Internet is provided to users who have cleared predetermined conditions. Can be downloaded. It is also possible to execute the encrypted program by using the key information and install the program on a computer.

  Further, the functions of the above-described embodiments are realized by the computer executing the read program. Also, the functions of the above-described embodiments can be realized by an OS running on the computer based on an instruction of the program, performing part or all of the actual processing.

It is a block circuit block diagram of the X-ray imaging system of 1st Embodiment. It is explanatory drawing of the inspection order displayed on the display. It is explanatory drawing of a display of imaging | photography information. It is a flowchart figure of the process sequence of 1st Embodiment. It is explanatory drawing of a display of quality information. It is a block circuit block diagram of 2nd Embodiment. It is a flowchart figure of the process sequence of 2nd Embodiment. It is explanatory drawing of the alerting | reporting of the necessity of a constancy test. It is a block circuit block diagram of 3rd Embodiment. It is a flowchart figure of the process sequence of 3rd Embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10, 10 ', 10 "detector management apparatus 11 Information transmission circuit 12 Information reception circuit 13 Quality information acquisition circuit 14 Imaging | photography information acquisition circuit 15 Quality information update circuit 16 Quality information display 17 Notification circuit 18, 28, 38 Information transmission / reception circuit 19 X-ray detector selection circuit 20, 20 ′, 30, 30 ′ X-ray imaging apparatus 21, 31 Information transmission circuit 22, 32 Information reception circuit 23, 33 Imaging control circuit 24, 34 Display 25, 35 Operation panel 26, 36 X-ray generation circuit 27, 37 X-ray detector

Claims (15)

A storage step of storing the result of the invariance test for each of the plurality of X-ray detectors in the storage unit;
A quality acquisition step in which the acquisition unit acquires the size information about each of the plurality of X-ray detectors and the result of the invariance test as quality information;
A spec acquisition step in which an acquisition unit acquires a required spec regarding the size and quality of the X-ray detector corresponding to imaging information used for imaging;
A selection step in which a selection unit selects at least one X-ray detector from the plurality of X-ray detectors from the acquired quality information and the required specifications;
An X-ray detector selection method comprising: The X-ray detector selection method according to claim 1, wherein in the selection step, the X-ray detector satisfying the required specifications is selected. In the selection step, when a plurality of the X-ray detectors satisfying the required specifications are specified, one X-ray detector having a high specification set as important quality information is selected. The method for selecting an X-ray detector according to claim 1. When the plurality of X-ray detectors satisfying the required specifications are specified in the selection step, the X-ray detector having the latest update date and time of the quality information is selected. Item 2. A method for selecting an X-ray detector according to Item 1. 2. The method according to claim 1, wherein, in the selection step, when there is no X-ray detector satisfying the required specification, the X-ray detector having the highest specification set as quality information to be emphasized is selected. A method for selecting the described X-ray detector. 6. The spec acquisition step includes acquiring information on an imaging part included in the imaging information and reading out the required specification set corresponding to the imaging part. A method for selecting an X-ray detector described in 1. The method for selecting an X-ray detector according to claim 1, further comprising a step of acquiring the imaging information from examination order information received from an external device. The method further includes a step of updating at least one of information on the number of times of imaging of the X-ray detector, information on a period of use, information on imaging frequency, and information serving as an index of imaging dose for each imaging. The method for selecting an X-ray detector according to any one of claims 1 to 7. In the storage step, the result of the invariance test repeated is stored in the storage unit,
In the quality acquisition step, the latest constancy test results are acquired.
The method for selecting an X-ray detector according to any one of claims 1 to 8. In the storing step, as a result of the invariance test, at least one information of spatial resolution power, contrast, noise, dynamic range, linearity, uniformity, detection efficiency, and sensitivity of the X-ray detector is stored as the invariant information. The method for selecting an X-ray detector according to any one of claims 1 to 9, wherein the storage unit stores the data every time a denaturation test is performed. At least one of the quality information, information about the number of times of imaging, information about the period of use, information about the frequency of imaging, and information that serves as an index of the sum of imaging doses, and a value based on the start of use and the quality The method for selecting an X-ray detector according to any one of claims 1 to 10, further comprising a step of separately displaying a value based on the end of the constancy test. When at least one of the information on the number of imaging, the information on the period of use, the information on the imaging frequency, and the information that is used as an index of the total of the imaging dose, which is counted from the last constancy test, exceeds the standard The method for selecting an X-ray detector according to any one of claims 1 to 11, further comprising a notification step of notifying a warning. The program for making a computer perform the selection method of any one of Claims 1 thru | or 12. Storing the result of the constancy test for each of the plurality of X-ray detectors in a storage unit;
A step in which the acquisition unit acquires the size information about each of the plurality of X-ray detectors and the result of the invariance test as quality information;
A step in which an acquisition unit acquires a required specification related to the size and quality of the X-ray detector corresponding to imaging information used for imaging;
A selection unit selecting at least one X-ray detector from the plurality of X-ray detectors based on the acquired quality information and the required specifications;
An X-ray detector selection method comprising: A storage unit for storing the results of constancy tests relating to repeated quality;
Quality acquisition means for acquiring size information about each of the plurality of X-ray detectors and quality information indicating the latest result of the constancy test;
Spec acquisition means for acquiring required specifications regarding the size and quality of the X-ray detector corresponding to imaging information used for imaging;
Selection means for selecting least one X-ray detector from the plurality of X-ray detector from said requirement specifications and the obtained quality information,
An apparatus for selecting an X-ray detector, comprising: