JP5152909B2 - Radiation image detection device - Google Patents

Description

  The present invention relates to a radiation image detection apparatus that performs quality control using a QC phantom and a quality control method thereof.

A quality control test using a QC phantom is performed in a radiation image detection apparatus such as a chest X-ray apparatus or a mammography apparatus. Various patterns are formed on the QC phantom, and a test is performed on predetermined items using a phantom image when the QC phantom is photographed (see, for example, Patent Documents 1-3). This quality control test is performed by calculating an evaluation value for each inspection item and determining whether the calculated evaluation value satisfies a set reference value. If the evaluation value does not satisfy the set reference value, an error output indicating that an abnormality has occurred is issued, and the maintenance of the radiation image detection apparatus is requested.
JP 2001-299736 A JP 2004-223138 A JP 2004-298617 A

  In Patent Documents 1-3, the test determines whether or not an evaluation value satisfies a set reference value, and a warning is issued when deterioration with time exceeds an allowable range. Therefore, even if the performance is deteriorated due to deterioration with time or the like, the radiation image detection apparatus is used in that state as long as it is within the allowable range. Here, when maintenance work is performed when there is a slight decrease in performance, it takes time and effort, but even if deterioration over time within the allowable range occurs, some adjustments should be made and used in the best condition. Is preferred.

  Therefore, the present invention provides a radiological image detection apparatus and a quality control method thereof that can efficiently adjust parameters in accordance with changes in the performance of the apparatus such as deterioration over time, using the evaluation results of tests using a QC phantom. It is for the purpose.

  The radiation image detection apparatus of the present invention includes a radiation source, a radiation detector that detects radiation transmitted through the subject when the subject is irradiated with radiation from the radiation source, and obtains a radiation image; At least one test item using a phantom image obtained by photographing a QC phantom as a subject in a radiological image detection apparatus comprising an imaging control means for controlling the operation of a radiation source and a radiation detector based on the imaging conditions Evaluation value calculating means for calculating an evaluation value for the above, and condition changing means for changing the shooting condition stored in the shooting condition storage means so that the evaluation value calculated by the evaluation value calculating means becomes the target evaluation value It is characterized by this.

  The quality control method of the radiation image detection apparatus of the present invention includes a radiation source, a radiation detector that detects radiation transmitted through the subject when the subject is irradiated with radiation from the radiation source, and acquires a radiation image, and imaging conditions A phantom image obtained by photographing a QC phantom as a subject in a quality control method for a radiation image detecting apparatus comprising an imaging control means for controlling operations of a radiation source and a radiation detector based on imaging conditions stored in a storage means Is used to calculate evaluation values for a plurality of test items, and the imaging conditions stored in the imaging condition storage means are changed so that the calculated evaluation values become target evaluation values.

  Here, the imaging conditions are conditions set when acquiring a radiographic image. For example, in addition to the tube current and focal spot size in the radiation source, the voltage applied to the radiation detector, the irradiation field stop, etc., radiation detection is performed. And gain for amplifying the signal charge output from the device.

Is mentioned. In addition, the test items may be of any type as long as they can be performed using a QC phantom. For example, the test items are listed in IEC61223, and in addition to the CNR value, spatial resolution, S / N ratio, chest wall defect, system Examples include sensitivity, image distortion, and image unevenness.

  Also, changing the shooting conditions means changing the shooting conditions stored in the shooting condition storage means so that various controls can be performed with the changed shooting conditions, and the shooting conditions themselves stored in the shooting condition storage means The amount of change may be stored without changing the shooting condition stored in the shooting condition storage unit, and the shooting control unit may read the shooting condition stored in the shooting condition storage unit and The shooting conditions may be changed based on the above.

  The radiological image detection apparatus may further include a pass / fail determination unit that determines whether the evaluation value calculated by the evaluation value calculation unit satisfies a preset setting reference range. At this time, the condition changing unit does not change the shooting condition when the pass / fail determination unit determines that the evaluation value satisfies the set reference range, and the shooting is performed when it is determined that the evaluation value does not satisfy the set reference range. The condition may be changed so that the evaluation value satisfies the set reference range. The acceptance / rejection determination means may output that an abnormality has occurred when it is determined that the evaluation value does not satisfy the set reference range. The setting reference range indicates a range of evaluation values indicating desired performance, and may be set according to the property of each evaluation value. For example, the upper limit and the lower limit of a predetermined range are used as setting reference values. When set, the pass / fail determination means determines whether or not the evaluation value is within a predetermined range. Further, when a predetermined upper limit value or lower limit value is set as the setting reference value, the pass / fail determination means determines whether the evaluation value is equal to or lower than the upper limit value or equal to or higher than the lower limit value.

  Further, the condition changing means may have a function of determining whether or not the amount of change from the initial value of the shooting condition is within a preset allowable range. Then, the condition changing means may output a warning when it is determined that the change amount of the photographing condition is not within the allowable range.

  Further, the condition changing means may have a function of outputting a warning when it is determined that the change amount from the previously changed shooting condition is larger than a predetermined change range.

  Further, when the test item is a CNR value, the evaluation value calculating means calculates the CNR value as an evaluation value using the pixel value of the CNR evaluation area in the phantom image, and the condition changing means sets the CNR value to the set CNR. You may change the tube current value which controls the radiation source which changes the tube voltage value which controls a radiation source so that it may become a value.

  Alternatively, when the test item is the spatial resolution of the phantom image, the evaluation value calculating means calculates the spatial resolution as an evaluation value using the pixel value of the resolution evaluation area in the phantom image, and the condition changing means Of the imaging conditions, the focal size of the radiation source may be changed so that the resolution becomes the set spatial resolution.

  Alternatively, when the test item is the S / N ratio, the evaluation value calculating means calculates the S / N ratio from the phantom image, and the condition changing means is such that the S / N ratio becomes the set S / N ratio. Of the imaging conditions, the radiation dose from the radiation source or the voltage applied to the radiation detector may be changed.

  The radiological image detection apparatus may further include a condition change enable / disable selecting unit that selects whether or not the imaging condition is changed by the condition changing unit. At this time, the condition change enable / disable selecting means may be capable of selecting whether or not to change imaging conditions corresponding to test items such as CNR value, spatial resolution, S / N ratio, etc. It may be possible to select whether or not to change for each photographing condition such as the focus size.

  According to the radiation image detection apparatus and the quality control method thereof of the present invention, a radiation source, a radiation detector that detects radiation when the subject is irradiated with radiation from the radiation source, and a radiation source and radiation detector Imaging control means for controlling the operation based on preset imaging conditions, and calculating an evaluation value for at least one test item based on a phantom image acquired by imaging a QC phantom, and the calculated evaluation value is By providing the condition changing means for changing the photographing condition so as to become the target evaluation value, when the test using the QC phantom is performed, the evaluation value calculated when judging the pass / fail of each test item is obtained. Since various parameters set as shooting conditions are used, shooting conditions must be set efficiently according to performance changes such as deterioration over time. It can be.

  Note that the apparatus further includes pass / fail determination means for determining whether or not the evaluation value calculated by the evaluation value calculation means satisfies a preset setting reference range, and the condition changing means is configured to set the evaluation value in the pass / fail determination means. When it is determined that the range is satisfied, the shooting conditions are not changed, and when it is determined that the evaluation value does not satisfy the set reference range, the shooting conditions are changed so that the evaluation value satisfies the set reference range. If so, radiation imaging can always be performed by a radiation image detection apparatus having desired performance.

  The condition changing unit has a function of determining whether or not the change amount from the initial value of the shooting condition is within a preset allowable range, and the change amount of the shooting condition is not within the allowable range. If a warning is output when the determination is made, the radiological image detection apparatus can be prevented from being used in an abnormal state by changing the imaging conditions, and safety can be improved.

  In addition, when the condition changing means has a function of outputting a warning when it is determined that the amount of change from the previously changed imaging condition is larger than the predetermined change range, the use of the radiation image detection device in an abnormal state Can be prevented and safety can be improved.

  Further, the test item is a CNR value, and the evaluation value calculating means calculates the CNR value as an evaluation value using the pixel value of the CNR evaluation area in the phantom image. The condition changing means sets the CNR value to the set CNR. When the tube current value for controlling the radiation source is changed among the imaging conditions so as to be a value, it is possible to prevent deterioration in image quality due to imaging of the subject with the contrast deteriorated.

  The test item is the spatial resolution of the phantom image, the evaluation value calculation means calculates the spatial resolution as an evaluation value using the pixel value of the resolution evaluation area in the phantom image, and the condition change means sets the spatial resolution. If the focal size of the radiation source is changed among the imaging conditions so as to obtain the spatial resolution, it is possible to prevent the image quality from being deteriorated due to the imaging of the subject with the spatial resolution deteriorated.

  Further, the test item is the S / N ratio, the evaluation value calculating means calculates the S / N ratio from the phantom image, and the condition changing means is such that the S / N ratio becomes the set S / N ratio. When the applied voltage to the radiation detector is changed among the imaging conditions, it is possible to prevent image quality deterioration due to imaging of the subject with the S / N ratio deteriorated.

  Further, if the apparatus further includes condition change enable / disable selecting means for selecting whether or not to change the shooting condition by the condition changing means, the user can select whether or not to change the shooting condition automatically. Therefore, user convenience can be improved.

  The radiation image detection apparatus of the present invention will be described below with reference to the drawings. FIG. 1 is a schematic diagram showing a preferred embodiment of a radiological image detection apparatus for acquiring radiographic images, and FIG. 2 is a block diagram thereof. The radiological image detection apparatus 1 is a mammography apparatus that acquires a so-called breast radiographic image, and includes a radiation source 2, a base 3, a support 4, an imaging table 5, and a pressing plate 6. The base 3 holds the support 4 so as to be movable in the arrow Z direction according to the position of the subject S. The radiation source 2 irradiates the subject S with radiation, and is accommodated in a radiation source accommodation portion 2 a attached to the upper part of the support 4.

  The imaging table 5 accommodates a radiation detector 10 that detects the radiation irradiated from the radiation source 2 and transmitted through the subject S and acquires the radiation image P, and is arranged below the support 4 so as to face the radiation source 2. Is attached. A pressing plate 6 that presses the subject S against the imaging table 5 is provided on the upper side of the imaging table 5, and the pressing plate 6 is attached to the support 4 so as to be movable in the direction of arrow Z. The pressure plate 6 is provided with thickness detecting means 93 for detecting the thickness D of the subject S by detecting the position of the pressure plate 6.

  Scattered ray removing means 7 is provided between the radiation source 2 and the radiation detector 10 in the imaging table 5. The scattered radiation removing means 7 absorbs (removes) the scattered component through the non-scattered component of the radiation. For example, it has a structure arranged in parallel by about 0.3 mm.

  The radiation detector 10 accumulates radiation image information composed of radiation transmitted through the subject S as an electrostatic latent image, and detects the radiation transmittance distribution as a radiation image by reading the accumulated electrostatic latent image. . The radiation detector 10 may be of any configuration as long as it detects radiation and outputs it as image information. For example, the radiation detector 10 may be a TFT solid detector or a light readout solid detector. Also good. Then, the radiation image P acquired by the radiation detector 10 is acquired by the image acquisition means 20 of the radiation image processing apparatus 100 of FIG. 2, and after various image processing is performed by the image processing means 30, an image is displayed on the display apparatus 100A. Is made.

  By the way, the radiation image detection apparatus 1 described above is periodically tested for performance using the QC phantom FM. The QC phantom FM has a predetermined pattern as shown in FIG. 3, for example, and various performance tests and evaluations are performed based on the phantom image FP when the QC phantom FM is photographed. The quality control test using the QC phantom FM includes an invariance test for monitoring the invariance of the performance of the device and a performance confirmation test for confirming the performance required for the radiation image detection apparatus 1. . The radiological image detection apparatus 1 is provided with functions for performing the quality control test and the performance confirmation test.

  Specifically, the radiation image detection apparatus 1 in FIG. 2 includes an evaluation value calculation unit 40, a pass / fail determination unit 50, and a condition change unit 60. The evaluation value calculation means 40 calculates evaluation values for a plurality of test items based on the phantom image obtained by photographing the QC phantom FM. In addition, the evaluation method of the various evaluation values about mammography is defined in IEC61223-3-2 (JIS Z 4752-3-2), for example.

  The test items include, for example, a chest wall defect test for calculating the chest wall defect amount using the coordinate information of the bar pattern FM1 provided at the outer edge of the QC phantom FM, and an aluminum MF2 having a thickness of 0.2 mm. CNR test that calculates the CNR value as the evaluation value C using the pixel value, the evaluation value is a value that is inversely proportional to the dose using the pixel value obtained from the region FM3 of 60 mm from the chest wall of the QC phantom FM and 20 × 20 mm in the left and right center A system sensitivity test calculated as C, and an image distortion in which a distance between ruled lines is calculated as an evaluation value C using a region FM4 in which ruled lines at 100 mm intervals indicated by triangular markers of the QC phantom FM are drawn Test, region consisting of metal and plastic (Mo / Mo = 28 kVp, region with transmittance equivalent to acrylic resin thickness of 40 mm ) Image uniformity test for calculating N / A when FM5 is uniformly irradiated with radiation as an evaluation value C, and using the thinnest region FM6 of the step wedge as the evaluation value C. Dynamic range test to be calculated, spatial resolution test to calculate SCTF (spatial resolution) as an evaluation value C using a bar pattern region FM7 inclined at 45 °, 2, 4, 8 cycles / mm, φ = 2 mm and predetermined contrast Low contrast detection capability test for calculating the cross-correlation value with the reference image as the evaluation value C using the region FM8 having a five-step step wedge region in which a density range of about ± 1 digit is formed with respect to the central density portion For example, a linearity / X-ray quality invariance test in which a difference between adjacent steps of the step wedge is calculated as an evaluation value C using FM9. Further, an S / N ratio test is performed in which the pixel average value / standard deviation (S / N ratio) on a uniform plane in the phantom image is calculated as the evaluation value C.

  In a normal radiographic image detection apparatus (and in the radiographic image detection apparatus 1, when the condition change enable / disable selection means 65 described later is turned OFF), the evaluation value C satisfies a desired state due to some influence such as deterioration over time. It may disappear. Below, the aspect which determines whether the evaluation value C is a desired state is demonstrated.

  The pass / fail judgment means 50 judges whether or not the evaluation value C calculated by the evaluation value calculation means 40 is within the usable range Cok. This usable range Cok is set according to the property of each evaluation value C. For example, when the upper limit value and the lower limit value of a predetermined range are set as the usable range Cok as shown in FIG. 4A, The pass / fail determination means 50 determines whether or not the evaluation value C is within the usable range Cok. 4B and 4C, when only a predetermined upper limit value or lower limit value is set as the usable range Cok, the pass / fail determination means 50 determines whether the evaluation value C is equal to or lower than the upper limit value, or It is determined whether or not the lower limit value is exceeded. When the pass / fail determination means 50 determines that the evaluation value C does not satisfy the usable range Cok, the radiological image detection apparatus 1 does not satisfy the performance for detecting the radiographic image, and is in an abnormal state. Is output to the display device 100A.

  As described above, when the evaluation value C slightly decreases in performance, it can be used as it is. However, in applications such as diagnostic imaging, the change in the evaluation value C should be as small as possible. preferable. Therefore, in the present invention, the pass / fail determination means 50 is made to determine whether or not the evaluation value C is within the set reference range Cref. Here, the set reference range Cref itself is only relatively close to the target evaluation value Ctg (for example, Cref is within ± 1% of Ctg). When the value C deviates from the target evaluation value Ctg as much as possible, it is preferable to change the imaging condition RC to compensate for the performance degradation immediately.

  The condition changing unit 60 in FIG. 2 changes the imaging condition RC so that the evaluation value C calculated by the evaluation value calculating unit 40 becomes the target evaluation value Ctg, and includes a condition calculating unit 61 and a change amount determining unit. 62. As the target evaluation value Ctg, for example, an evaluation value of the radiological image detection apparatus 1 at the time of shipment in which performance deterioration such as deterioration with time does not occur is set. Here, a method for calculating the imaging condition RC when the test items are the CNR value, the spatial resolution, and the S / N ratio will be specifically described.

  When the test item is a CNR value, the condition calculation means 61 changes the tube voltage value of the radiation source 2 in the imaging condition RC, whereby the evaluation value C (CNR value) becomes the target evaluation value Ctg (target CNR value). Change as follows. Here, the condition calculation means 61 stores the relationship between the CNR value and the tube voltage value in advance, and the CNR value decreases as the thickness of the subject increases, and increases as the tube voltage value increases. . Therefore, the condition calculation means 61 calculates the difference between the tube voltage values for the evaluation value C to be the target evaluation value Ctg as the change amount ΔRC of the imaging condition RC. Then, when performing normal imaging, the imaging control unit 80 operates the radiation source control unit 91 and the radiation source 2 by changing the imaging condition RC stored in the imaging condition storage unit 70 by the change amount ΔRC.

When the test item is the spatial resolution, the condition calculation means 61 changes the focus size FS of the radiation set as the imaging condition RC, so that the evaluation value C (spatial resolution) becomes the target evaluation value Ctg (target spatial resolution). Adjust so that Here, the spatial resolution can be represented by a blur width h on the radiation detector 10 as shown in FIG. Here, when the focus size is FS, the distance between the radiation source 2 and the radiation detector 10 is L, the distance from the radiation detector 10 to the subject S is a, and the thickness of the subject is D, the reference observation position Zs (0 The relationship between the blur width h on the radiation detector 10 and the focus size FS of the image of the subject S in <Zs ≦ D) can be obtained by the following equation (1).
FS = (L−a−Zs) h / (a + Zs) (1)

  As can be seen from the equation (1), the focus size FS and the blur width h are in a proportional relationship, so the condition changing unit 61 calculates Ctg / C as the change amount ΔRC. Then, when performing normal imaging, the imaging control unit 80 operates the radiation source control unit 91 and the radiation source 2 by changing the focal point size FS calculated by Expression (1) by the change amount Ctg / C times.

When the test item is the S / N ratio, the condition calculating means 61 adjusts the radiation dose mAs value of AEC (Auto Exposure Control) or changes the applied voltage of the radiation detector 10 to thereby evaluate the evaluation value C (S / N Ratio) is adjusted to be the target evaluation value Ctg (target S / N ratio). For example, when the evaluation value C = 9 and the target evaluation value Ctg = 10, the condition calculation means 61 calculates (C / Ctg) ^−1/2 = 100 / 81≈1.23 as the change amount ΔRC. Then, when performing normal imaging, the imaging control unit 80 operates the radiation source control unit 91 and the radiation source 2 by changing the predetermined mAs value by (C / Ctg) ^−1/2 ≈1.23 times.

  That is, as shown in FIG. 6A, when the evaluation value C decreases due to deterioration with the passage of time or the like from the time of shipment, the condition calculation unit 61 is configured so that the evaluation value C falls within a set reference range Cref indicating a desired performance value. The sequential shooting conditions RC are changed.

The change amount determination unit 62 in FIG. 2 determines whether or not the change amount ΔRC from the initial value RC ₀ of the imaging condition RC by the condition calculation unit 61 is within the allowable range RC _A as shown in FIG. 6B. Is. The allowable range RC _A is determined by restrictions on use of the apparatus such as a radiation dose and functional limits such as a maximum voltage that can be applied. The initial value may be, for example, the value of the photographing condition RC at the time of shipment, or may be set by a photographer such as an engineer. When the change amount determination unit 62 determines that the change amount ΔRC of the imaging condition RC does not fall within the allowable range RC _{A at the} predetermined time t _err , the change amount determination unit 62 outputs a warning to notify the user to that effect. On the other hand, when the change amount determination unit 62 determines that the change amount ΔRC of the shooting condition RC is within the allowable range RC _A , the change amount determination unit 62 changes the shooting condition RC stored in the shooting condition storage unit 70. Note that the imaging condition RC may be changed by changing the imaging condition RC itself stored in the imaging condition storage unit 70, or the change amount ΔRC without changing the content stored in the imaging condition storage unit 70. May be stored and the shooting condition RC may be changed using the change amount ΔRC each time the operation control means 80 refers to the shooting condition storage means 70.

  Thus, by determining not only the evaluation value C but also the change amount ΔRC, it is possible to ensure safety when using the radiation image detection apparatus 1. That is, when the tube voltage or the voltage applied to the radiation detector 10 is changed in order to set the evaluation value C for the CNR value or S / N ratio described above to the target evaluation value Ctg, the radiation dose becomes the exposure allowance. It is also conceivable that it will be set exceeding. Therefore, by determining the change amount ΔRC by the change amount determination means 62, it is possible to reliably prevent the exposure allowable amount from being exceeded.

Further, the change amount determining means 62, the change amount ΔRCd has a large and determining features than change area RC _B from the previous. Then outputs determined that unexpected error warning when it is determined that the change amount ΔRCd from previous larger than change area RC _B. Thereby, use of the radiation image detection apparatus 1 in an abnormal state can be prevented and safety can be improved.

  The condition change enable / disable selecting means 65 selects whether or not to change the imaging condition RC by the condition change means 60. For example, the condition change enable / disable selecting means 65 selects whether or not the change is possible according to the input from the input unit operated by the user. To do. For example, as shown in FIG. 7, the imaging condition RC (tube voltage) corresponding to the test of the CNR value and S / N ratio among the test items such as the CNR value, spatial resolution, S / N ratio, etc. Value, mAs value) is selected to be changed. Then, the condition changing unit 60 does not change the imaging condition RC (focus size) corresponding to the spatial resolution test. In this way, since the user can select whether or not to automatically change the shooting condition RC, the user-friendliness can be improved. Instead of selecting for each test item as described above, it may be possible to select whether or not to change for each imaging condition RC such as a tube voltage value and a focus size.

  FIG. 8 is a flowchart showing a preferred embodiment of the quality control method of the radiation image detection apparatus 1 of the present invention. The quality control method will be described with reference to FIGS. First, in a state where the QC phantom FM is arranged on the imaging table 5, the QC phantom FM is irradiated with radiation from the radiation source 2, and a phantom image is detected by the radiation detector 10 (step ST1). Note that the QC phantom test is performed using the imaging conditions RC that are sequentially changed. Next, the evaluation value calculation means 40 calculates the evaluation value C for each test item using the phantom image (step ST2). Then, the pass / fail determination means 50 determines whether or not the evaluation value C satisfies the set reference range Cref (step ST3).

When the pass / fail determination means 50 determines that the evaluation value C does not satisfy the set reference range Cref, the condition calculation means 61 calculates an imaging condition RC that makes the evaluation value C the target evaluation value Ctg (step ST4). Thereafter, the change amount determination means 62 determines whether or not the change amount ΔRC from the calculated initial value RC ₀ of the imaging condition RC is within the allowable range RC _A (see step ST5, FIG. 6A). warning is outputted when the non within the range RC _A (step ST6). On the other hand, when the change amount ΔRC is within the allowable range RC _A , it is further determined whether or not the change amount ΔRCd from the previous imaging condition RC is within the change range RC _B (see step ST7, FIG. 6B). When the change amount ΔRCd is not within the change range RC _B , a warning is output (step ST8). On the other hand, when it is determined that the change amount ΔRCd from the previous shooting condition RC is within the change range RC _B , the change amount ΔRC is stored in the shooting condition storage unit 70 as the shooting condition RC (step ST9). Then, the operation of the radiation image detection apparatus 1 is controlled based on the imaging condition RC changed in the imaging control unit 80.

  According to the above embodiment, the radiation source 2, the radiation detector 10 that acquires the radiation image by detecting the radiation transmitted through the subject S when the subject S is irradiated with radiation, and the radiation source 2 and an imaging control means 80 that controls the operation of the radiation detector 10 based on a set imaging condition RC, based on a phantom image acquired by imaging the QC phantom FM as a subject. Evaluation value calculating means 40 for calculating the evaluation value C for at least one test item, and condition changing means 60 for changing the imaging condition RC so that the evaluation value C calculated by the evaluation value calculating means 40 becomes the target evaluation value Ctg. When the test using the QC phantom FM is performed, the evaluation value C calculated when determining the pass / fail of each test item is obtained. And use, to change the various parameters are set as an imaging condition RC, it is possible to set the imaging condition RC tailored to performance changes such time degradation efficiently.

  As shown in FIG. 6A, the apparatus further includes pass / fail determination means 50 for determining whether or not the evaluation value C calculated by the evaluation value calculation means 40 is within the set reference range Cref. When the means 50 determines that the evaluation value C is within the set reference range Cref, the imaging condition RC is not changed. When the evaluation value C is determined not to be within the set reference range Cref, the imaging condition RC is changed. Sometimes, radiography can be performed by a radiological image detection apparatus having a desired performance.

Further, as shown in FIG. 6B, the condition changing means 60 has a function of determining whether or not the change amount ΔRC from the initial value RC ₀ of the shooting condition RC is larger than the allowable range RC _A. If a warning is output when it is determined that the change amount ΔRC of the condition RC is larger than the allowable range RC _A , the radiographic image detection apparatus 1 is used in an abnormal state as a result of changing the imaging condition RC. Can be prevented and safety can be improved.

Further, when changing the imaging condition RC every time, if it is determined that the change amount ΔRCd from the previous time is larger than the predetermined change range RC _B , it is determined as an unexpected abnormality and a warning is output. As a result of changing the imaging condition RC, it is possible to prevent the radiation image detection apparatus 1 from being used in an abnormal state and to improve safety.

  Further, the test item is a CNR value, and the evaluation value calculation means 40 calculates the CNR value as an evaluation value using the pixel value of the CNR evaluation region in the phantom image. When the tube current value is changed in the shooting condition RC so that becomes the target evaluation value Ctg, it is possible to prevent image quality deterioration due to shooting of the subject with the CNR value deteriorated.

  The test item is the spatial resolution of the phantom image, the evaluation value calculation means 40 calculates the spatial resolution as an evaluation value using the pixel value of the resolution evaluation area in the phantom image, and the condition change means 60 If the focal point size FS of the radiation source is changed so that the evaluation value C becomes the target evaluation value Ctg, the image quality deterioration due to the photographing of the subject with the spatial resolution deteriorated is prevented. be able to.

  Further, the test item is the S / N ratio, and the evaluation value calculation means 40 calculates the S / N ratio from the phantom image, and the radiation dose of the radiation source 2 or the radiation detector 10 in the imaging condition RC. When the applied voltage is changed so that the evaluation value C becomes the target evaluation value Ctg, it is possible to prevent the image quality from being deteriorated due to the photographing of the subject with the S / N ratio deteriorated.

  Further, as shown in FIGS. 1 and 6, if the apparatus further includes condition change enable / disable selecting means 65 for selecting whether or not to change the shooting condition RC by the condition changing means 60, the user can set the shooting condition RC. Since it is possible to select whether or not to change automatically, it is possible to improve the usability of the user.

  The embodiment of the present invention is not limited to the above embodiment. In the above-described embodiment, the case where the radiation source 2 or the radiation detector 10 is controlled is illustrated. However, for example, the processing parameter in the image processing unit 30 may be changed.

  In addition, although the case where the radiation image detection apparatus 1 is a mammography apparatus is illustrated in FIG. 1, it may be applied to an apparatus that performs quality control inspection using a QC phantom FM such as a chest X-ray apparatus or a nondestructive inspection apparatus. it can.

  Furthermore, in the said embodiment, although illustrated about the case where exposure conditions, such as a tube voltage value, a focus size, and a mAs value, are changed, it is not limited to this, Various imaging conditions used when radiography is performed. It may be changed.

  In the above embodiment, the setting reference range Cref is determined, and when the evaluation value C deviates from this, the change amount of the imaging condition RC is calculated. However, the present invention is not limited to this, and the setting reference range Cref is determined. Instead, the change amount of the imaging condition RC may always be calculated based on the difference between the evaluation value C and the target evaluation value Ctg.

The schematic diagram which shows preferable embodiment of the radiographic image detection apparatus of this invention. The block diagram which shows preferable embodiment of the radiographic image detection apparatus of this invention The schematic diagram which shows an example of QC phantom used for the quality control test of the radiographic image detection apparatus of FIG. The graph which shows the relationship between the setting reference | standard range set in the acceptance determination means of FIG. 1, and an evaluation value The graph which shows the relationship between the setting reference | standard range set in the acceptance determination means of FIG. 1, and an evaluation value The graph which shows the relationship between the setting reference | standard range set in the acceptance determination means of FIG. 1, and an evaluation value Schematic diagram showing the relationship between the focus size and spatial resolution (blur width) changed in the condition calculation means of FIG. The graph which shows a mode that the evaluation value calculated in an evaluation value calculation means is settled in a setting reference | standard range by the change of the imaging conditions by the condition change means of FIG. The graph which shows an example of the change amount from the initial value of the imaging condition by the condition changing means of FIG. 1 and the change amount from the previous imaging condition A table showing a state in which whether or not to change the photographing condition for the quality control test is selected by the condition change enable / disable selecting unit in FIG. The flowchart which shows preferable embodiment of the quality control method of the radiographic image detection apparatus of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Radiation image detection apparatus 2 Radiation source 10 Radiation detector 40 Evaluation value calculation means 50 Pass / fail judgment means 60 Condition change means 61 Condition calculation means 62 Change amount determination means 65 Condition change enable / disable selection means 80 Imaging control means 70 Imaging condition storage means 100 Radiation image processing apparatus C Evaluation value Cref Setting reference range Ctg Target evaluation value FM QC phantom FP Phantom image P Radiation image RC Imaging condition S Subject

Claims (10)

Based on a radiation source, a radiation detector that detects the radiation transmitted through the subject when the subject is irradiated with radiation from the radiation source, and obtains a radiation image, and an imaging condition stored in the imaging condition storage means A radiological image detection apparatus comprising: an imaging control means for controlling operation of the radiation source and the radiation detector;
Evaluation value calculation means for calculating an evaluation value for at least one test item using a phantom image obtained by photographing a QC phantom as the subject;
Condition changing means for changing the imaging condition stored in the imaging condition storage means so that the evaluation value calculated by the evaluation value calculating means becomes a target evaluation value ;
The condition changing unit has a function of determining whether or not a change amount from the initial value of the shooting condition is within a preset allowable range, and the change amount of the shooting condition is within the allowable range. A radiological image detection apparatus , which outputs a warning when it is determined that it is not . Based on a radiation source, a radiation detector that detects the radiation transmitted through the subject when the subject is irradiated with radiation from the radiation source, and obtains a radiation image, and an imaging condition stored in the imaging condition storage means A radiological image detection apparatus comprising: an imaging control means for controlling operation of the radiation source and the radiation detector;
Evaluation value calculation means for calculating an evaluation value for at least one test item using a phantom image obtained by photographing a QC phantom as the subject;
Condition changing means for changing the imaging condition stored in the imaging condition storage means so that the evaluation value calculated by the evaluation value calculating means becomes a target evaluation value ;
The radiological image detection apparatus according to claim 1, wherein the condition changing means outputs a warning when it is determined that the amount of change from the previously changed imaging condition is larger than a predetermined change range . Based on a radiation source, a radiation detector that detects the radiation transmitted through the subject when the subject is irradiated with radiation from the radiation source, and obtains a radiation image, and an imaging condition stored in the imaging condition storage means A radiological image detection apparatus comprising: an imaging control means for controlling operation of the radiation source and the radiation detector;
Evaluation value calculation means for calculating an evaluation value for at least one test item using a phantom image obtained by photographing a QC phantom as the subject;
Condition changing means for changing the imaging condition stored in the imaging condition storage means so that the evaluation value calculated by the evaluation value calculating means becomes a target evaluation value ;
The condition changing unit has a function of determining whether or not a change amount from the initial value of the shooting condition is within a preset allowable range, and the change amount of the shooting condition is within the allowable range. A warning is output when it is determined that it is not, and a warning is output when it is determined that the change amount from the previously changed shooting condition is larger than a predetermined change range. Radiation image detection device. Based on a radiation source, a radiation detector that detects the radiation transmitted through the subject when the subject is irradiated with radiation from the radiation source, and obtains a radiation image, and an imaging condition stored in the imaging condition storage means A radiological image detection apparatus comprising: an imaging control means for controlling operation of the radiation source and the radiation detector;
Evaluation value calculation means for calculating an evaluation value for at least one test item using a phantom image obtained by photographing a QC phantom as the subject;
Condition changing means for changing the imaging condition stored in the imaging condition storage means so that the evaluation value calculated by the evaluation value calculating means becomes a target evaluation value ;
The test item is a spatial resolution of the phantom image, the evaluation value calculation unit has a function of calculating the spatial resolution from the phantom image as the evaluation value, and the condition changing unit includes the imaging condition. A radiological image detection apparatus , wherein the focus size of the radiation source is changed so that the evaluation value becomes the target evaluation value . Based on a radiation source, a radiation detector that detects the radiation transmitted through the subject when the subject is irradiated with radiation from the radiation source, and obtains a radiation image, and an imaging condition stored in the imaging condition storage means A radiological image detection apparatus comprising: an imaging control means for controlling operation of the radiation source and the radiation detector;
Evaluation value calculation means for calculating an evaluation value for at least one test item using a phantom image obtained by photographing a QC phantom as the subject;
Condition changing means for changing the imaging condition stored in the imaging condition storage means so that the evaluation value calculated by the evaluation value calculating means becomes a target evaluation value ;
A radiological image detection apparatus , further comprising: a condition change enable / disable selecting unit that selects whether or not to change the imaging condition by the condition changing unit . Based on a radiation source, a radiation detector that detects the radiation transmitted through the subject when the subject is irradiated with radiation from the radiation source, and obtains a radiation image, and an imaging condition stored in the imaging condition storage means A radiological image detection apparatus comprising: an imaging control means for controlling operation of the radiation source and the radiation detector;
Evaluation value calculation means for calculating an evaluation value for at least one test item using a phantom image obtained by photographing a QC phantom as the subject;
Condition changing means for changing the imaging condition stored in the imaging condition storage means so that the evaluation value calculated by the evaluation value calculating means becomes a target evaluation value ;
The condition changing unit has a function of determining whether or not a change amount from the initial value of the shooting condition is within a preset allowable range, and the change amount of the shooting condition is within the allowable range. When it is determined that it is not, a warning is output.
A radiological image detection apparatus , further comprising: a condition change enable / disable selecting unit that selects whether or not to change the imaging condition by the condition changing unit . Based on a radiation source, a radiation detector that detects the radiation transmitted through the subject when the subject is irradiated with radiation from the radiation source, and obtains a radiation image, and an imaging condition stored in the imaging condition storage means A radiological image detection apparatus comprising: an imaging control means for controlling operation of the radiation source and the radiation detector;
Evaluation value calculation means for calculating an evaluation value for at least one test item using a phantom image obtained by photographing a QC phantom as the subject;
Condition changing means for changing the imaging condition stored in the imaging condition storage means so that the evaluation value calculated by the evaluation value calculating means becomes a target evaluation value ;
The condition changing means outputs a warning when it is determined that the change amount from the shooting condition changed last time is larger than a predetermined change range,
A radiological image detection apparatus , further comprising: a condition change enable / disable selecting unit that selects whether or not to change the imaging condition by the condition changing unit . The apparatus further comprises pass / fail determination means for determining whether or not the evaluation value calculated by the evaluation value calculation means satisfies a preset setting reference range, wherein the condition changing means includes the evaluation value in the pass / fail determination means. Is determined to satisfy the set reference range without changing the shooting condition, and when it is determined that the evaluation value does not satisfy the set reference range, the shooting condition is changed and the evaluation value is the radiation image detection apparatus according to any one of the four claim 1, characterized in that to satisfy the set reference range. The test item is a CNR value of the phantom image, the evaluation value calculation unit has a function of calculating the CNR value from the phantom image as the evaluation value, and the condition changing unit includes the imaging condition the radiation image detection apparatus according to any one of claims 1 to 8, wherein the tube voltage value for controlling the radiation source that the evaluation value is to change such that the target evaluation value. The test item is an S / N ratio of the phantom image, the evaluation value calculation unit has a function of calculating the S / N ratio from the phantom image as the evaluation value, and the condition changing unit one of claims 1, wherein the evaluation value the voltage applied to the radiation dose or the radiation detector from the radiation source of the imaging condition is to change such that the target evaluation value 9 A radiological image detection apparatus according to claim 1.

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