KR102004643B1 - Apparatus for Radiography Training - Google Patents

Abstract

The present invention relates to a radiography simulation device capable of detecting error of radiography, including a radiation generation device model which does not emit actual radiation, a detector model, a data input means, a threshold DB, an image material DB, a display means and the like. The radiography simulation device further includes a plurality of distance sensors capable of measuring a position of the radiation generation device model and the detector model, an angle sensor capable of measuring a photographing angle of the radiation generation device model, and the like. If a position, angle, SID or the like of the radiation generation device model and the detector model adjusted by a trainee or the like exceeds a threshold value, the radiography simulation device is terminated by outputting an error message, and if the position, angle, SID or the like of the radiation generation device model and the detector model adjusted by a trainee or the like does not exceed the threshold value, an image material with the identical photographed part, photographing posture and photographing angle among previously stored image materials is found and showed, thereby allowing a trainee or the like participating in practical training to achieve the same effect as in training by operating an actual radiography device with a radiography simulation device which does not emit actual radiation.

Description

[0001] Apparatus for Radiography Training [0002]

The present invention relates to a simulated radiographic apparatus capable of detecting a radiographic error. In more detail, in a simulated radiographic apparatus including a model radiation generator and a model detector in which actual radiation is not emitted, the position of the model radiation detector and the position of the model radiation generator are measured And an angle sensor and a threshold value DB capable of measuring the angle of view of the model radiation generator, and the position or angle of the model radiation generator and the model detector adjusted by the operator or the trainee If the threshold value stored in the threshold value DB is exceeded, an error message is issued and terminated. If the threshold value is not exceeded, a matching portion, a shooting posture, and a shooting angle among the previously stored image data are found The students who participated in the exercises will be exposed to radiation without any risk or concern. As to allow the hands-radiography, according to the present invention to simulate the radiography apparatus is not emitting radiation can achieve the same effect as by the actual train operation the radiographic apparatus.

The use of radiation, which was initiated by Röntgen's discovery of X-rays in 1895, has been useful for many years to the present, and has contributed greatly to the diagnosis and treatment of patients in the medical field. Even in modern times, radiography technology is a big part of the medical field. In recent years, with the development of advanced technology, digital radiation imaging equipment combined with digital technology has been developed, which contributes greatly to diagnosis and effective treatment more accurately and quickly than before.

In order to take a radiographic image using a radiological imaging device and conduct a test, it is important to train professional workers who have acquired professional knowledge and experience. In addition, the medical radiology education to nurture such professional manpower should be accompanied by theoretical education to acquire the theoretical knowledge, and practical training for the improvement of practical ability and accumulation of experience. However, there have been many limitations in the practice of radiography and diagnostic devices, such as the problem of radiation exposure to the students participating in the practice. Therefore, in order to solve the radiation exposure problem for the trainees, it is necessary to practice the human shape using the human phantom phantom without directly radiographing the patient, or simulator implemented in the software image An alternative has been suggested and applied to practice through.

However, the method using the human phantom has a problem that high practice effect can not be expected due to the limitation of the patient's posture in a radiological examination requiring various patient postures according to the examination method. In other words, since the radiographic test is for the patient, practicing the patient posture with the same object as the human body or human body can enhance the practical effect in the practical training. However, since the phantom is a model only, it can not take a variety of photographing postures, so it is difficult to practice. In the case of general phantom, it is possible to have a slightly different attitude. However, most of the phantom is used in the educational field where the financial condition is poor because the price is too high. Therefore, There has been a problem that the practical effect is not large.

In addition, even though there is no direct radiation exposure to the trainee because it is a phantom phantom, the problem of radiation exposure to the trainees participating in the operation of the radiation equipment still remains because the equipment uses actual radiation. Has been raised. In order to construct a safe environment, it is necessary to design and build a radiation defense system in accordance with the radiation safety management regulations for the radiography room, and the students are required to wear a personal radiation measuring instrument and periodically measure and report The installation of radiation imaging equipment, etc., must be reported to the administrative office and regularly inspected. Therefore, the burden of financial burden and administrative power have been increased.

In the meantime, the simulation training method is one step further from the previous lecture-oriented education, and the students experience clinical medical care and crisis situations by bringing them closer to the clinical situation. Therefore, it is an integrated education to simultaneously acquire knowledge and practice, . In addition, simulation uses a simulator to improve learner's decision making ability and reasoning ability, and it is possible to evaluate immediately. In addition, simulator training can be simulated and iterative training can minimize mistakes in actual situation and demonstrate high - level technology. Because of these advantages, simulation education has been developed in various fields as well as medical field. Various types of simulation training have been developed in the field of radiation image education. However, the practice of practicing through the simulator implemented in the software image screen is not performed by the users themselves but by the alternative input means such as a mouse or a keyboard, There is a problem that the sense of presence is deteriorated, and accordingly, the problem that the practice effect and the experience acquisition effect are remarkably deteriorated has been pointed out.

In order to solve the above problems, a simulated radiographic apparatus capable of detecting a radiographic error according to the present invention includes a model radiation generator and a model detector which do not emit actual radiation, a data input means, a threshold value DB, An image data DB, a display means, and the like, including a model radiation generator, a plurality of distance sensors capable of measuring the position of the model detector, and an angle sensor capable of measuring a photographing angle of the model radiation generator If the position, angle, SID, etc. of the model radiation generator and the model detector adjusted by the trainee etc. exceeds the threshold value, an error message is issued and terminated. If the threshold value is not exceeded, Finding and matching the recorded image, the shooting position, the shooting angle and the recorded image Lock manner, and that the students, such as participating in practice provide a simulated radiographic apparatus in a simulated radiation imaging apparatus of the actual radiation that is not emitted can achieve the same effect as training and the actual operation of the radiation imaging device in order.

According to an aspect of the present invention, there is provided a simulated radiation imaging apparatus capable of detecting a radiation imaging error according to the present invention, including a stand, a model detector, a model radiation generator, a data input unit, And a warning means, wherein the stand is fixedly disposed at a position a certain distance from the model radiation generating apparatus; Wherein the model detector has a first distance sensor that is capable of measuring the height of the detector from the bottom surface to the center of the model detector, the surface being attached to the stand such that the surface thereof faces the direction of the model radiation generator, ; Wherein the model radiation generating apparatus includes a second distance sensor, a third distance sensor, a fourth distance sensor, and an angle sensor, which are arranged to be movable in vertical and horizontal directions, The third distance sensor measures SID (Source to Image Distance), which is a horizontal distance between the model detector and the model radiation generator, and the fourth distance sensor Which is a distance traveled by the model radiation generator in parallel with the surface and bottom surface of the model detector, is measured by a vertical line on the surface of the model detector and a virtual radiation of the model radiation generator A first tube angle &thetas; and an imaginary center line of the imaginary radiation are projected on the surface of the model detector, Measuring the angle between the horizontal line of claim 2 Tube angle (φ) and; Wherein the data inputting means receives from the operator a photographing condition including a photographing part, a photographing posture, a photographing angle, a tube voltage and a tube current amount; Wherein the threshold value DB stores an adjustment threshold value for each of the model detector and the model radiation generator according to an imaging condition; Wherein the control means collects sensing information from the first distance sensor, the second distance sensor, the third distance sensor, the fourth distance sensor, and the angle sensor, Calculating a distance from a central point of the radiation in which the center line meets the surface of the model detector to a center point of the model detector to obtain a center distance and obtaining an adjustment threshold value from the threshold value DB according to the shooting condition input from the operator, If the at least one of the sensing information or the center distance exceeds the adjustment threshold value, the threshold error message is generated through the alert means and the process is terminated; And the like.

Another embodiment of a simulated radiographic apparatus capable of detecting a radiographic error according to the present invention includes a table, a model detector, a model radiation generator, a data input means, a threshold value DB, a control means and an alarm means The first table movement distance being a widthwise movement distance of the table and the second table movement distance being a movement distance in the longitudinal direction, A first distance sensor and a second distance sensor, each of which can be measured; The model detector includes a third distance sensor disposed inside the table and horizontally movable in the longitudinal direction of the table and capable of measuring a detector moving distance that the model detector horizontally moves; The model radiation generator is arranged to be capable of vertical movement in the upper portion of the table and horizontal movement in the width direction and longitudinal direction of the table, and the fourth distance sensor, the fifth distance sensor, the sixth distance sensor, Wherein the fourth distance sensor measures a SID (Source to Image Distance), which is a vertical distance between the model detector and the model radiation generator, and the fifth distance sensor and the sixth distance sensor measure the model radiation And a second tube movement distance that is a longitudinal movement distance, wherein the angle sensor measures a distance between a vertical line on the surface of the model detector and a vertical line on the surface of the model radiation, A first tube angle &thetas;, which is an angle between a center line in the imaginary radiation of the generator, and a line projected on the surface of the model detector, Measuring a second tube angle ([phi]) that is an angle between a center-to-center direction of the width of the detector; Wherein the data inputting means receives from the operator a photographing condition including a photographing part, a photographing posture, a photographing angle, a tube voltage and a tube current amount; Wherein the threshold value DB stores an adjustment threshold value for each of the model detector and the model radiation generator according to an imaging condition; The control means collects sensing information from the first distance sensor, the second distance sensor, the third distance sensor, the fourth distance sensor, the fifth distance sensor, the sixth distance sensor, and the angle sensor And calculating a distance from the sensing information to a center distance between the central point of the radiation in which the center line of the imaginary radiation meets the surface of the model detector and the center point of the model detector to obtain a center distance, If the at least one of the sensing information or the center distance exceeds the adjustment threshold value, generates a threshold error message through the alert means and terminates the process; And the like.

According to another aspect of the present invention, there is provided an apparatus for detecting a radiographic error, the apparatus further comprising a video data DB, an image processing means, and a display means in addition to the above- Stores radiographic image data photographed for each photographing position by photographing position and photographing angle; Wherein the control unit controls one of the radiation image data from the image data DB according to the photographing part, the photographing posture, and the photographing angle when the sensing information and the center distance are within the adjustment threshold value, ; Wherein the image processing means produces an adjustment image for the simulation image according to the tube voltage and the tube current amount and displays the adjustment image on the display means; The photographing condition may further include body shape information of the examinee. The photographing condition may include whether or not a grid is inserted and a focal length, a lattice width, a lattice height, and a lattice spacing of the grid And further includes grid information including the grid information.

As described above, according to the present invention, a simulated radiographic apparatus capable of detecting a radiographic error can have the same effect as a simulated radiographic apparatus that does not emit actual radiation, It is effective. Particularly, since radiation is not used at all, there is an advantage that not only the trainee who acts as a patient, but also the equipment operator and the trainee who operate the apparatus can receive training free from the risk of radiation exposure.

It is also possible to provide a SID, a plurality of distance sensors capable of measuring the location of a model radiation generator and a detector, and an angle sensor capable of measuring the angle of the model radiation generator, If the position or angle of the model radiation generator and the simulator detector exceeds the threshold value, the error message is output and the trainee can train the model radiator and the model detector accurately.

Threshold values for the SID, the position of the model radiation generator and the detector are not uniformly set but are customized threshold values set for the shooting region, the shooting posture and direction, the shooting angle, and the like, Since the stored data is searched according to the shooting area and applied, the actual education students can apply the field because the errors are generated if the model radiation generator and the model detector are not accurately positioned according to the shooting area according to the situation.

Also, in the calculation of whether or not the threshold value is exceeded, it is necessary to simply compare or determine whether the set value adjusted by the trainee or the like exceeds the threshold value with respect to the position and angle of the model radiation generator, the position of the model detector, However, since the center distance between the center point of the imaginary radiation source of the model radiation generator and the center point of the model detector is calculated in order to comprehensively determine whether the threshold value is exceeded, There is an effect that it is possible to accurately judge whether or not the image is correct.

In addition, in calculating the center distance, it is possible to accurately calculate the center distance even when an expensive gyro sensor or a position sensor is not used because a unique algorithm that can be calculated using only an angle sensor and a distance sensor is created and used.

In addition, the existing image data is stored in the image data DB according to the photographing position, direction, and photographing angle of each photographing site, and then the photographing conditions, that is, the photographing position, the photographing posture, Since the matching image data is searched and displayed on the display means as a simulated image, it is possible to maximize the effect of the practical training because it gives the same effect as the observation of the actual image of the student himself or herself.

In addition, since the image processing means produces an adjusted image according to the tube voltage and the tube current inputted by the trainee for the simulation image and displays it on the display means, when the tube voltage or the tube current amount is insufficient or excessively set, There is an effect that the image data according to the shortage or excess can be made and displayed, and as a result, it is possible to grasp whether the tube voltage and the tube current set by the student are proper or have a mistake.

1A shows a case in which a radiation beam is normally irradiated onto a detector surface in radiography.
1B shows a case where the radiation beam is irradiated abnormally on the detector surface in radiography.
2 is a side view of a simulated radiography apparatus using a stand type detector according to the present invention.
3 is a top view of a simulated radiographic apparatus using a stand-type detector according to the present invention.
4 is a block diagram of a simulated radiographing apparatus using a stand-type detector according to the present invention.
FIG. 5 shows the concept of a virtual radiation, a center line in a virtual ray and a center point in a radiation in a simulated radiography apparatus capable of detecting a radiographic error according to the present invention.
FIG. 6 is a conceptual view of a tube height, a center line in a virtual ray, and a center point in a radiation in a simulated radiography apparatus capable of detecting a radiographic error according to the present invention.
Fig. 7 shows an example of calculating the center distance of a stand-type detector in a simulated radiography apparatus capable of detecting a radiographic error according to the present invention.
8 shows a second tube angle in a simulated radiographic apparatus capable of detecting a radiographic error according to the present invention.
9 is an illustration of a threshold value DB in a simulated radiography apparatus capable of detecting a radiographic error according to the present invention.
10 is an illustration of an image data DB in a simulated radiography apparatus capable of detecting a radiographic error according to the present invention.
11 is an illustration of radiation image data stored in an image data DB in a simulated radiographic apparatus capable of detecting a radiographic error according to the present invention.
12 shows a side view of a simulated radiography apparatus using a table type detector according to the present invention.
13 is a front view of a simulated radiography apparatus using a table type detector according to the present invention.
FIG. 14 shows a configuration of a simulated radiography apparatus using a table-type detector according to the present invention.
FIG. 15 illustrates an example of calculating a center distance of a table-type detector in a simulation radiographic apparatus capable of detecting a radiographic error according to the present invention.

The present invention will be described in detail in order to clarify the objects and features described above, so that those skilled in the art can easily carry out the technical idea of the present invention. In describing the present invention, it is to be understood that any known technology related to the present invention has already been known in the art, and if a detailed description of the known technology is considered to unnecessarily obscure the gist of the present invention, It will be omitted.

In addition, although the term used in the present invention is selected as a general term that is widely used at present, there are some terms selected arbitrarily by the applicant in a specific case. In this case, since the meaning is described in detail in the description of the relevant invention, It is to be understood that the present invention should be grasped as a meaning of a term that is not a name of the present invention. The terminology used in the description of the embodiments is used only to describe a specific embodiment, and is not intended to limit the embodiments. The singular expressions include plural expressions unless the context clearly dictates otherwise.

The embodiments are capable of various modifications and may have various additional embodiments, in which specific embodiments are shown in the drawings and are described in further detail in connection with the drawings. It should be understood, however, that the embodiments are not intended to be limited to the particular forms, but are to be understood to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the embodiments.

Expressions such as " first, " " second, " " first, " or " second, " and the like may be used to distinguish the various components of the embodiments. For example, the above expressions do not limit the order or importance of the components. That is, the above expressions can be used to distinguish one element from another, and expressions such as " including " or " including " And the like, and does not limit the one or more additional functions, operations, or components.

Hereinafter, a radiation simulation control method performed by the radiation imaging simulation system according to the present invention will be described with reference to the accompanying drawings.

In an actual radiographing apparatus, the radiation beam passes through a human body or the like to be photographed and comes into contact with a detector, and radiation can be taken only in an area where the radiation beam touches the detector. The radiation generated from the focus (F) of the tube is spread uniformly within a certain range around the center line, and is emitted within the size range of the detector through the irradiation field limiting device and reaches the detector. The radiation flux irradiated on the detector must be irradiated in a balanced manner on the detector centered on the center point of the detector. If the radiation beam deviates from the center of the detector and is deviated to one side only, the radiation image does not appear because the radiation beam does not reach the opposite side. Therefore, it is important for the actual radiography to ensure that the radiation beam reaches the center of the detector centered on a balanced basis. If the radiograph is shifted to one side, the radiation image will only partially appear and the imaging will fail. The exception is when intentionally dividing the screen and taking pictures at one corner of the detector in order to capture multiple areas on one screen.

FIG. 1A shows a case where a radiation beam to be irradiated is normally irradiated in a detector surface in an actual radiography, and FIG. 1B shows a case where a part of radiation in an actual radiography is irradiated abnormally out of a detector plane, The radiation image x formed on the detector is normally photographed in the range of the radiation x. However, when the radiation x is partially coincident with the surface of the detector 200 as shown in FIG. 1B, only the portion of the radiation X corresponding to the detector is exposed and the remaining portion of the detector 200 The human body part in that part is excluded from the shooting, and eventually the shooting will fail. In addition, apart from this, even if the radiation flux x coincides with the surface of the detector 200, if the angle in the radiation, that is, the tube angle, is too tilted, It is also important to limit the tube angle to a certain threshold value, and the shooting distance, or SID (Source to Image Distance), is also within a certain range. In addition, when the grid is used, the focal length of the grid and the focal length of the grid should be considered because the sharpness of the radiation image may be deteriorated if the focal distance and SID of the grid deviate from the error range.

Therefore, in the radiation simulation control method performed by the radiographing simulation system according to the present invention, in the case of detecting the case where the radiation velocity x is not accurately transmitted on the model detector 200, 200 and the model radiographic apparatus 300 are measured to calculate whether the virtual radiation flux x coincides with the surface of the model detector 200. When the virtual radiation flux x is detected by the model detector 200, The SID, the photographing angle, and the like are out of a preset range or threshold value, it is determined as a photographing error and the process is stopped. Accordingly, it is possible for the trainee or the like to recognize that the position or angle of the model detector or the model radiation generating apparatus adjusted by the trainee or the like has been adjusted incorrectly.

In the radiation simulation control method performed by the radiation imaging simulation system according to the present invention, it is desirable to calculate whether the virtual radiation flux (x) coincides with the surface of the model detector 200 through the measurement values of various sensors However, how far the center point (c) of the virtual radiation flux (x) deviates from the center point (230) of the model detector (200) is calculated and determined. In some cases, for example, when the tube angle that generates the virtual radiation flux (x) in the stand-type detector is 0, it is possible to determine the height difference even if the center distance is not measured, x) and the height difference between the detector 200 and the tube.

2 is a side view of a simulated radiography apparatus using a stand type detector according to an embodiment of a simulated radiography apparatus capable of detecting a radiography error according to the present invention. And FIG. 4 shows a block diagram thereof. As shown in FIG. Hereinafter, a simulated radiography apparatus using a stand-type detector according to an embodiment of the present invention will be described with reference to FIGS. 2 to 4. FIG. 2 and 3, a simulated radiographic apparatus using a stand-type detector includes a stand 100 fixed vertically to a floor surface 10, A stereoscopic detector 300 disposed at a certain distance from the stand 100 and a model radiation generator 300 installed at a distance from the model detector 200 and capable of horizontally moving, ). In the following description, the height, the moving distance, the position or the angle of the model radiation generating apparatus 300 is the height of the tube, the height of the tube, A moving distance, a tube position, a tube angle, or the like. Also, the stand 100 may be installed movably with respect to the bottom surface 10.

2, a front view of the stand 100 and the model detector 200 are shown in the left space of the stand 100 and the sides of the model detector 200 for the sake of understanding . It is preferable that the model detector 200 is movable in the vertical direction V1 by manual operation or automatic operation. In the following description, a horizontal line formed at the central portion of the model detector 200 in the longitudinal direction is referred to as a center horizontal line 210, a vertical line formed at a central portion in the horizontal direction is referred to as a central vertical line 220, 210 and the center vertical line 220 are referred to as a center point 230 of the model detector 200 will be described. 4, the model detector 200 includes a first distance sensor 201 and the first distance sensor 201 detects the center point of the bottom surface 10 and the model detector 200, It is preferable to measure the distance h1 between the center point 230 of the model detector 200 and the detector height h1 which is the height with respect to the center point 230 of the model detector 200. [

2 and 3, the model radiation generating apparatus 300 can be moved in the vertical direction V2 by manual operation or automatic operation and can be reciprocated in the direction of the model detector 200 or in the opposite direction It is preferable to make the horizontal movement H1 and the horizontal movement H2 capable of reciprocating in a direction parallel to the surface of the model detector 200 and the bottom surface 10, The first horizontal movement support means 320 and the second horizontal movement support means 330 can be vertically or horizontally moved through the first horizontal movement support means 310 and the second horizontal movement support means 330. The vertical movement support means 310, It is of course possible to integrate the first horizontal movement support means 320 and the second horizontal movement support means 330 into one moving support means (not shown). In addition, the model radiation generator 300 should be able to adjust the shooting angle by manual operation or automatic operation, that is, to adjust the tube angle, which is the angle adjustment for the direction in which the radiation is irradiated. A1 and the angle adjustment A2 in the horizontal direction. However, in some cases, it is possible to configure only the vertical angle adjustment A1.

4, the model radiation generator 300 may include an angle sensor 301, a second distance sensor 302, a third distance sensor 303, and a fourth distance sensor 304 desirable. 7) between the vertical line ab of the model detector 200 (see FIG. 7) and the imaginary radiation center line (x0, see FIG. 7) of the model radiation generator 300 (See FIG. 7) projected on the surface of the model detector 200 and the line bc (see FIG. 7) projected on the surface of the model detector 200 (See Fig. 7), which is an angle between the central horizontal line 210 and the second distance sensor 302, and the second distance sensor 302 measures the second tube angle from the bottom surface 10 to the model radiation generating apparatus 300 And the third distance sensor 303 measures the SID (Source to Image Distance), which is a horizontal distance between the model detector 200 and the model radiation generator 300, , And the fourth distance sensor (304) detects that the model radiation generator (300) To 200 surface and to measure the said bottom surface (10) Tube Distance (m1) in parallel to the moving distance and the preferred. The reference position may be a position where the model radiation generator 300 is perpendicular to the central vertical line 220 of the model detector 200 and the surface of the model detector 200, It is preferable to measure the distance from the reference position to the negative or positive distance.

In FIG. 3, it can be seen that the model radiation generator 300 is moved by a distance m1 to a point deviated from the vertical line with respect to the center point 230 of the model detector 200, where m1 corresponds to the tube moving distance I will do it. 2, the height difference h2 between the tube height h2 of the model radiation generator 300 and the center point 230 of the model detector 200 is equal to the distance m2. The angle sensor 301 can simultaneously measure the first tube angle? And the second tube angle? With a single angle sensor. The first tube angle? And the second tube angle? It is also possible to have a respective angle sensor for measuring the 2 tube angle phi.

Hereinafter, the remaining components of the simulated radiography apparatus using the stand type detector will be described with reference to FIG. As shown in FIG. 4, the stand-type radiographic apparatus includes the control unit 500, the data input unit 510, the alarm unit 520, and the threshold value DB 530 in addition to the above- But it is also possible to include the image data DB 560, the image processing means 540 and the display means 550, more preferably.

First, the control means 500 controls the first distance sensor 201, the second distance sensor 302, the third distance sensor 303, the fourth distance sensor 304 and the angle sensor 301 The control unit 500 acquires the center distance from the sensing information and obtains an adjustment threshold value according to the shooting condition input from the operator from the threshold value DB 550 to determine at least one of the sensing information, If the center distance exceeds the adjustment threshold value, it is preferable that the threshold value error message is generated through the alert means 520 and then the process is terminated. The reason for doing this is that, as described above, in the actual radiography, since the radiation beam must be accurately transmitted to the detector, in the simulated radiography apparatus for training, the case where the radiation beam is not accurately transmitted to the detector is detected, It is preferable to provide a means for informing the user.

Therefore, the control unit 500 recognizes the positions and angles of the model detector 200 and the model radiation generator 300, and determines the center point c of the radiation from the center of the model detector 200 The detector height h1, the tube height h2, the SID, the tube movement distance m1, the first tube angle?, And the second tube angle? ) Are collected and used.

The control unit 500 collects the sensing information from the sensing information from the model detector 200 based on the radial center point c of the center line x0 of the imaginary radiation and the surface of the model detector 200, To calculate the center distance. A method of obtaining the center distance will be described with reference to FIGS. 5 to 8. FIG. FIG. 5 shows the concept of a virtual radiation, a center line in a virtual radiation, and a center point in a radiation in a model radiation generator when a stand-type detector of a simulated radiography apparatus capable of detecting a radiographic error according to the present invention is used FIG. 6 shows the concept of the tube height, the center line of the imaginary radiation and the center point of the radiation, FIG. 7 shows an example of calculating the center distance, and FIG. 8 shows the case of the second tube angle measurement .

(Xm, x0, xn) from the virtual focus F (a point), which is a virtual point assumed to emit a virtual radiation beam, from the model radiation generating apparatus 300 having a predetermined downward inclination angle as shown in FIG. The point c at which the imaginary center line x0 in the imaginary radiation meets the surface of the model detector 200 corresponds to the center point in the radial direction x0, c). The center point c of the radiation varies depending on the height difference (m2, see Fig. 6) between the model radiation generator 300 and the model detector 200, the tube angle of the model radiation generator 300, 5 and FIG. 6, the center point c of the radiation is formed below the center horizontal line 210 of the model detector 200. However, since FIGS. 5 and 6 are side views, it can not be determined whether the radial center point c is located off the center vertical line 220 or on the central vertical line 220. This can be judged in the description with reference to FIG.

6 shows a line segment ab where the vertical line on the surface of the model detector 200 meets the virtual focus F of the model radiation generator 300 and the center line center line x0 of the virtual center line, Is the horizontal distance from the virtual focus F of the model radiation generator 300 to the surface of the model detector 200, which corresponds to the SID (Source to Image Distance). The difference m2 between the height h2 of the segment ab and the height h1 of the center horizontal line 210 is a difference between the height of the model radiation generator 300 and the model detector 200, The distance between the center horizontal line 210 of the model detector 200 and the focal point F of the model radiation generator 300 will be a distance indicating the difference in the tube height.

Hereinafter, a method of calculating the center distance from the sensing information will be described with reference to FIG. As described above, the control means 500 may collect the SID, the tube moving distance m1, the first tube angle? And the second tube angle? From the sensing information The height difference m2 may be calculated from the height of the model radiation generator 300 and the height of the model detector 200. The difference between the height of the model radiation generator 300 and the height h1 of the model detector 200, And the height of the horizontal line 210. 7, the center distance will be a distance between the center point 230 of the model detector 200 and the center point c of the radiation. When the coordinates of the center point c in the radiation are grasped, . In order to grasp the coordinate c (x, y) of the center point c in the radiation, the coordinates b (x, y) for the point b must be grasped. The coordinates ab (x, y) = b (m1, m2) for the point b will be the position where the device 300 meets vertically with the surface of the model detector 200, Will be.

Since the angle formed by the center line x0 in the imaginary radiation source 300 of the model radiation generator 300 and the line segment ab is the first tube angle?, The center line x0 of the imaginary radiation is located on the surface of the model detector 200 The length of the line segment bc projected on the screen may be obtained by SID x tan?. Also, the angle formed by the line segment bc with the center horizontal line 210 will be φ as the second tube angle. As shown in FIG. 8, the second tube angle φ is a value measured in the range of 0 to 360 degrees. Since the line segment bc is at an angle toward the upper limit of 3, it can be seen that φ is within the angular range φ3 of 180 degrees to 270 degrees. The coordinate of the center point c in the radiation moves from the point b by the line segment bd in the horizontal direction and moves by the line segment dc in the vertical direction. The line segment bd is a value obtained by multiplying the line segment bc by cos? It will be the value obtained by multiplying the line segment bc by sinφ. Accordingly, the coordinates of the center point c in the radiation may be expressed as follows.

(SID x tan?) x cos?), (m2 + (SID x tan?) x sin?))

Here, m1 is a numerical value obtained by measuring the movement distance of the tube from the reference position in a negative or positive direction. In FIG. 7, the point b is a distance horizontally shifted by a distance m1 in the negative direction. M2 is a value obtained by subtracting the detector height h1 which is the height of the model detector from the tube height h2 and is a positive value when the tube height h2 is larger than the detector height h1, 7, the point b is a distance vertically shifted by m2 in the positive direction from the center horizontal line 210 of the model detector 200, so that the tube height h2 is the height of the detector (h1). Since? Is a value (? 3) existing at the three upper limit as described above, both cos? And sin? Will have a negative value. Therefore, it can be seen that the point c (x, y) is shifted further from the point b (m1, m2) to the negative region. Therefore, since the center distance between the center point 230 of the model detector 200 and the center point c of the radiation is a distance between the center point (0,0) and c (x, y), it can be obtained by the following equation will be.

Center distance = SQRT ((Tube Distance + (SID x tan θ) x cosφ) 2 + ((+ (SID x tan θ height Tube height detector)) x sinφ) ^2), where SQRT is the square root (Square Root), θ Is the first tube angle, and? Is the second tube angle.

The control unit 500 calculates a distance difference between the center point 230 of the model detector 200 and the center point c of the radiation in accordance with the photographing condition input by the operator from the threshold value DB 530 Detector center-distance center distance threshold value ", which is a threshold value of the center distance, is obtained. If the center distance is greater than the" detector-center distance radial distance threshold " It is preferable that the threshold value for the center distance is set to an appropriate value reflecting the situation such as the photographing position, the photographing angle, and the SID. Also, the control means 500 obtains the SID threshold value range, the Tube angle threshold value or the detector-tube height difference threshold value according to the photographing condition inputted from the operator from the threshold value DB 530, And the difference (m2) between the first tube angle (?) Or the tube height (h2) and the detector height (h1). If the difference exceeds the threshold value range, the alarm means It is preferable to cause the process to end after generating the corresponding error message.

9, the threshold DB 530 stores the adjustment threshold value for each of the model detector 200 and the model radiation generator 300. The threshold DB 530 stores the adjustment threshold for each of the model detector 200 and the model radiation generator 300, It is desirable to store threshold values such as the distance range of each SID, the allowable range of the tube angle, the allowable range of height difference between the model detector and the model radiation generator, and the allowable range of the center distance. It is also desirable to store the data in a database for ease of retrieval or the like. However, in some cases, it is possible to store data in a form of data rather than DB. However, the data shown in FIG. 9 are only illustrative numerals for the sake of understanding, and are not actually applicable data.

When the center distance, the SID, the first tube angle, the difference between the height of the detector and the height of the tube are within respective threshold values, the control means 500 controls the height of the model detector 200 It is determined that adjustment of the position and angle of the model radiation generator 300 has been normally performed and it is preferable that one of the radiation image data stored in the image data DB 560 is selected as a simulation image. 10, the image data DB 560 is a database constructed so as to search for and retrieve radiographic image data photographed according to a photographing posture, a direction, a photographing angle, etc. according to a photographing site, Illustrative data is shown in FIG. In addition, it is preferable that an adjustment image processed by the image processing means 540 is generated and displayed on the display means according to the tube voltage and the tube current amount for the simulation image.

On the other hand, the data inputting means 510 receives photographing conditions including the photographing site, photographing posture, photographing angle, tube voltage and tube current amount from the operator, and the operator completes the adjustment to the model detector or the model radiation generator It is also preferable to use an input / output interface device such as a touch pad or the like for inputting on the screen so that input results and the like can be recognized immediately. However, it is also possible to use conventional input means such as a keyboard or a button. Preferably, the alarm means 520 can use sound, light, or image as means for generating an alarm when the position, angle, or the like of the model detector or the model radiation generator adjusted by the operator exceeds a threshold value.

The image processing means 540 is configured to generate an adjustment image by reflecting the tube voltage and the tube current amount inputted from the operator with respect to the simulation image selected by the control means 500 from the image data DB 560, It is preferable that the adjusted tube voltage and the tube current amount are compared with the target tube voltage and the target tube current stored in advance to calculate the adjustment value. However, it is more preferable to compare the target tube voltage and the target tube current amount with each other in accordance with the photographing region and the photographing posture. The target tube voltage and the target tube current amount according to the photographed region, (Not shown), and search and obtain them.

It is preferable that the adjustment image created by the image processing means 540 is displayed on the screen through the display means 550. In some cases, the display means 550 may also serve as the alarm means 520 It is possible. In this case, the alarm content can be displayed on the display means 550 as text or an image.

In the simulated radiographing apparatus capable of detecting a radiographic error according to the present invention, the photographing condition may further include body shape information of the examinee. Alternatively, it is possible to store radiographic image data according to the body, sex, age, etc. in the image data DB 560, and to provide the radiographic image data by providing the radiographic image data according to the photographing conditions It is possible.

In addition, in the simulated radiation imaging apparatus capable of detecting a radiographic error according to the present invention, grid information including whether or not a grid is inserted into the photographing condition and a focal length, a lattice width, a lattice height, It is also preferable to include the above-mentioned structure. If the difference between the SID and the grid focal length is greater than the grid focal distance threshold, a grid error message is generated. And the adjustment image may be processed by reflecting the insertion of the grid when manufacturing the adjustment image for the simulated radiographic image.

12 to 15 are views for explaining a simulated radiography apparatus using a table type detector, which is another embodiment of a simulated radiography apparatus capable of detecting a radiography error according to the present invention, Fig. 13 is a front view, and Fig. 14 is a conceptual diagram of the configuration. And Fig. 15 shows an example of calculating the center distance in the table type simulated radiography apparatus. Hereinafter, a simulated radiographing apparatus using a table-type detector of the simulated radiography apparatus according to the present invention will be described with reference to FIGS. 12 to 15. FIG.

12 and 13, the table-type simulated radiography apparatus includes a simulated radiation generator 300 installed to be capable of horizontal movement, vertical movement, and angle adjustment, A model detector 200 capable of horizontally moving the table 150 in the longitudinal direction of the table 150 so that the table 150 capable of horizontally moving in the width direction and the longitudinal direction is disposed on the table rest 155, . The table 150 may be movable in the vertical direction as well. 12 shows a top view of the table 150, the model detector 200, and the model radiation generator 300, for the sake of clarity, at the bottom of the table cradle 155 shown in FIG. 12 . The model detector 200 is located inside the table 150, but is represented by a solid line for convenience. In addition, the position of the model radiation generator 300 is indicated at a position different from that shown in the upper part, for convenience of explanation.

12 and 13, the table 150 is a rectangle having a size that can be laid by a person serving as a patient and is reciprocated horizontally in the longitudinal direction of the table 150 by manual operation or automatic operation (H4 And a reciprocating horizontal movement (H5) in the width direction of the table 150 is possible. The lower end of the table includes the table rest 155, which preferably supports the table 150 horizontally on the bottom surface 10. 14, the table 150 includes a first table movement distance, which is a horizontal movement distance in the width direction H5 of the table 150 from a reference position, and a second table movement distance, which is horizontally moved in the length direction H4, And a second distance sensor that is capable of measuring a second table movement distance, which is a second distance traveled by the first distance sensor, to a negative or positive distance, respectively. The reference position will be described later.

The model detector 200 is disposed inside the table 150 to allow reciprocating horizontal movement (H3) in the longitudinal direction of the table 150 within the length range of the table 150, And a third distance sensor 201 capable of measuring a detector moving distance, which is a distance that the model detector 200 horizontally moves (H3) in the negative or positive direction from the reference position. The third distance sensor 201 may be placed inside the table 150 without measuring the distance to the model detector 200 to measure the moving distance of the model detector 200.

Meanwhile, the model radiation generator 300 can be moved in the vertical direction V2 by manual operation or automatic operation, and can be moved in the longitudinal direction of the table 150 along with the reciprocating horizontal movement H1, The horizontal movement support means 310, the first horizontal movement support means 320, and the second horizontal movement support means 330 may be provided so that the vertical movement support means 310, the first horizontal movement support means 320, The vertical movement support means 310, the first horizontal movement support means 320 and the second horizontal movement support means 330 can be moved vertically or horizontally through one of them, It is of course possible to integrate them into the system. In addition, the model radiation generator 300 should be able to adjust the photographing angle, that is, the tube angle, by a manual operation or an automatic operation. The angle adjusting unit A3, which rotates in the longitudinal direction of the table, It is preferable that all of the angle adjustment (A4) is possible.

14, the model radiation generator 300 may include an angle sensor 301, a fourth distance sensor 302, a fifth distance sensor 303, and a sixth distance sensor 304 desirable. 15) between the vertical line ab of the model detector 200 (see FIG. 15) and the imaginary radiation center line (x0, see FIG. 15) of the model radiation generator 300 (See FIG. 15) projected on the surface of the model detector 200 and the line bc (see FIG. 15) projected on the surface of the model detector 200 And the fourth distance sensor 302 measures the second tube angle (see Fig. 15), which is the angle between the model direction detector 200 and the model radiation generator 300, And the fifth distance sensor 303 measures the SID (Source to Image Distance), which is a vertical distance of the model radiation generator 300, from the reference position to the horizontal position along the longitudinal direction of the table 150 A second tube travel distance is measured as a negative or positive distance, and the sixth distance sensor 30 4) preferably causes the model radiation generator 300 to measure the first tube travel distance horizontally moved from the reference position along the width direction of the table 150 to a negative or positive distance.

Here, the reference position is a position in which the position of the center point c of the radiation in the state where the first tube angle? Is 0 and the position of the center point 230a of the model detector 200 (see FIG. 14) The first table moving distance, the second table moving distance, the first tube moving distance, and the first table moving distance, respectively, of the model detector 200, the table 150, and the model radiation generator 300, And the second tube movement distance is a negative or positive distance about the reference position.

Meanwhile, the angle sensor 301 can simultaneously measure the first tube angle? And the second tube angle? With one angle sensor, and each angle sensor can be used to measure the first tube It is of course also possible to respectively measure the angle [theta] and the second tube angle [phi].

12 shows a state in which the model radiation generator 300 is moved away from the vertical line of the center point 230 of the model detector 200 by the distance m2 in the longitudinal direction of the table 150, Assuming that the center point 230 of the model detector 200 is at the reference position, m2 is the length in the longitudinal direction and m2 is deviated from the reference position, The length of the device 300, that is, the second tube movement distance. 13 shows a state in which the center point 230 of the model detector 200 is moved by a distance m1 in the width direction of the table 150 from the vertical straight line directly below the model radiation generator 300, Assuming that the model radiation generator 300 is at the reference position, m1 is the widthwise distance of the table 150, and the model detector 200 is a widthwise movement relative to the table 150 M1 will correspond to the widthwise horizontal movement distance of the table 150, that is, the first table movement distance.

Hereinafter, with reference to FIG. 14, the remaining components of the table type simulated radiographic apparatus, which is one embodiment of the present invention, will be described. As shown in FIG. 14, the table-type simulated radiographing apparatus includes a control unit 500, a data input unit 510, an alarm unit 520, and a threshold value DB 530 in the same manner as the stand- But it is also possible to include the image data DB 560, the image processing means 540 and the display means 550, more preferably.

First, the control means 500 controls the first distance sensor 151, the second distance sensor 152, the third distance sensor 201, the fourth distance sensor 301, the fifth distance sensor The threshold value DB 550, the sixth distance sensor 304, and the angle sensor 301, calculates a center distance from the sensing information, If the at least one of the sensing information or the center distance exceeds the adjustment threshold value, an error message for the corresponding threshold value is generated through the alarm means 520, It is preferable to terminate the process.

As described above, in the actual radiography, since the radiation beam must be able to be accurately transmitted to the detector, in the simulated radiation imaging apparatus for training the radiation beam detector, means for detecting the case where the radiation beam is not accurately transmitted to the detector, In order to achieve this, in the present invention, the distance between the center point c in the radiation of the model radiation generator 300 and the center point 230a of the model detector 200 is measured, It is determined that a shooting error occurs and the process is stopped.

Therefore, in the table type simulated radiographing apparatus, the control means 500 controls the positions of the model detector 200 and the table 150 and the position and angle of the model radiation generator 300, The SID, the first tube movement distance, the second tube movement distance, and the second tube movement distance are detected from the center point 230a of the model detector 200, The first table movement distance, the second table movement distance, the detector movement distance, the first tube angle?, And the second tube angle? Are collected and calculated.

The control unit 500 collects the sensing information from the model detector 200 using the sensing information from the center point c of the radial center of the virtual radiation ray center line x0 to the surface of the model detector 200 200 to calculate the center distance. Hereinafter, a method of calculating the center distance from the sensing information will be described with reference to FIG. 15, the center distance will be the distance between the center point 230a of the model detector and the center point c of the radiation, and the coordinates of the radial center point c from the center point 230a of the model detector The center distance can be calculated.

As shown in FIG. 15, since the position where the model radiation generator 300 vertically meets the surface of the model detector 200 is b, the segment a-b will be the SID. On the other hand, the point b is located at a distance from the central vertical line 220a of the model detector in the width direction by m1 in the negative direction, which is a value obtained by subtracting the first table moving distance from the first tube moving distance . This is because the table 150 and the model radiation generator 300 are movable in the width direction of the table 150 and the model radiation generator 300 moves a certain distance in the width direction, The model detector 150 in the table 150 is also moved if the table 150 has moved in the same direction so that the vertical radiation 220a of the model radiation generator 300 and the model detector 150 is moved, Is a value obtained by subtracting the first table moving distance from the first tube moving distance. Therefore, in FIG. 15, m1 = the first tube travel distance-the first table travel distance. When moving in opposite directions, the absolute value of m1 becomes larger because one of them has a negative value.

Further, the point b is located at a distance of m2 in the longitudinal direction of the table from the center horizontal line 210a of the model detector. This position is a sum of the second table travel distance and the detector travel distance at the second tube travel distance Will be subtracted. This allows both the table 150, the model radiation generator 300 and the model detector 200 to move in the longitudinal direction of the table 150, and the m2 can be transmitted to the model radiation generator 300 Since the distance between the model detector 200 and the model detector 200 is dependent on the movement of the table 150. That is, when the table 150 is moved away from the model radiation generator 300, the model detector 200 is also distant. In addition, in the table 150, the model detector 200 moves in the same direction The distance between the model radiation generator 300 and the model detector 200 becomes the sum of the second table travel distance and the detector travel distance. Therefore, in FIG. 15, m2 = second tube moving distance - (second table moving distance + detector moving distance)

Therefore, the coordinates of the point b are as follows.

(second tube moving distance - (second table moving distance + detector moving distance))) = ((x, y) = b

On the other hand, the angle formed by the center line x0 in the virtual ray of radiation of the model radiation generator 300 with the line segment ab will be θ as the first tube angle and the center line x0 in the virtual ray of radiation will be detected by the model detector 200, The length of the line segment bc projected on the surface of the substrate can be found by SID x tan?. Also, the angle formed by the line segment bc with the center horizontal line 210 will be φ as the second tube angle. As described above with reference to FIG. 8, the second tube angle φ is a value measured from 0 ° to 360 ° In Fig. 15, since the line segment bc is at an angle toward the 1-upper limit, it can be seen that phi is within the angular range (phi 1, Fig. 7) of 0 degree to 90 degrees.

The coordinate of the center point c in the radiation moves from the point b by the line segment bd in the horizontal direction and moves by the line segment dc in the vertical direction. The line segment bd is a value obtained by multiplying the line segment bc by cos? It will be the value obtained by multiplying the line segment bc by sinφ. Accordingly, the coordinates of the center point c in the radiation may be expressed as follows.

(second tube moving distance - (second table moving distance + detector moving distance) + (SID x tan?) x cos?), )) + (SID x tan?) X sin?)))

Here, since? Is a value (? 1) existing at one upper limit as described above, both cosφ and sin? Will have a positive value. Therefore, it can be seen that the point c (x, y) is shifted toward the positive region from the point b (m1, m2) in the negative region in the drawing and calculation. Therefore, the center distance between the center point 230 of the model detector and the center point c of the radiation is a distance between the center point (0,0) and c (x, y), and therefore, it can be obtained by the following equation.

Center distance = SQRT ((first tube travel distance - first table travel distance + (SID x tan?) X cos?) ² + (second tube travel distance - (second table travel distance + detector travel distance) + x tan θ) x sin φ) ² )

Where SQRT is the square root, θ is the first tube angle, and φ is the second tube angle.

The control unit 500 reads the threshold value DB 530 from the threshold value DB 530 and determines whether the distance between the center point of the model detector 200 and the center point of the radiation c, The center-of-gravity center distance error threshold value ', and if the center distance is greater than the' detector-center-of-radiation distance threshold value ', it is preferable to terminate the process after generating the center- It is more preferable that the threshold value for the distance is set to each appropriate value reflecting the situation such as the shooting region, the shooting posture and direction, the shooting angle, and the SID. The control unit 500 obtains the SID threshold value range and the Tube angle threshold value according to the shooting condition input from the operator from the threshold value DB 530 and outputs the SID and the first tube angle? And when the SID or the first tube angle? Exceeds the threshold value range, it is preferable to generate the corresponding error message through the alert means 520 and then terminate the process. The threshold value DB 530 is the same as that described above for the simulated radiography apparatus using the stand type detector, and therefore will not be described.

Meanwhile, when the center distance, the SID, the first tube angle, and the like are within respective threshold values, the control unit 500 controls the position of the model detector 200, the position of the model radiation generator 300, It is preferable that one of the radiation image data stored in the image data DB 560 is selected as a simulation image. The image data DB 560 and the radiation image data The data is also the same as the above-described contents of the simulated radiographing apparatus using the stand type detector, and will not be described here. The data input means 510, the alarm means 520, the image processing means 540 and the display means 550 may also be used in combination with the above-described contents in the description of the simulated radiography apparatus using the stand- It is assumed to be omitted.

Although the present invention has been described with reference to the above examples, the present invention is not necessarily limited to these examples, and various modifications may be made without departing from the scope of the present invention. Therefore, the examples disclosed in the present invention are not intended to limit the scope of the present invention and are not intended to limit the scope of the present invention. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

100 stands 150 tables
200 Detector
201 / 201a center horizontal line 220 / 220a center vertical line
230 / 230a center point
300 Model radiation generator
310 vertical movement support means 320 first horizontal movement support means 320,
330 second horizontal movement supporting means
500 control means
510 data input means
520 Alert Means
530 threshold value DB
540 Image processing means
550 display means
560 video data DB

Claims (4)

A simulated radiographic apparatus including a stand, a model detector, a model radiation generator, a data input means, a threshold value DB, a control means, and an alarm means,
The stand is fixedly disposed at a position a certain distance from the model radiation generating apparatus;
Wherein the model detector has a first distance sensor that is capable of measuring the height of the detector from the bottom surface to the center of the model detector, the surface being attached to the stand such that the surface thereof faces the direction of the model radiation generator, ;
Wherein the model radiation generating apparatus includes a second distance sensor, a third distance sensor, a fourth distance sensor, and an angle sensor, which are arranged to be movable in vertical and horizontal directions, The third distance sensor measures SID (Source to Image Distance), which is a horizontal distance between the model detector and the model radiation generator, and the fourth distance sensor Which is a distance traveled by the model radiation generator in parallel with the surface and bottom surface of the model detector, is measured by a vertical line on the surface of the model detector and a virtual radiation of the model radiation generator A first tube angle &thetas; and an imaginary center line of the imaginary radiation are projected on the surface of the model detector, Measuring the angle between the horizontal line of claim 2 Tube angle (φ) and;
Wherein the data inputting means receives from the operator a photographing condition including a photographing part, a photographing posture, a photographing angle, a tube voltage and a tube current amount;
Wherein the threshold value DB stores an adjustment threshold value for each of the model detector and the model radiation generator according to an imaging condition;
Wherein,
- collecting sensing information from the first distance sensor, the second distance sensor, the third distance sensor, the fourth distance sensor and the angle sensor,
Calculating a distance from the sensing information to a center of the pattern detector from a center of gravity of the radiation in which the center line of the imaginary radiation meets the surface of the model detector to obtain a center distance,
- determining an adjustment threshold value in accordance with the shooting condition input from the operator from the threshold value DB and, when at least one of the sensing information or the center distance exceeds the adjustment threshold value, Terminating the process after generating the message; A radiographic imaging device capable of detecting a radiographic error, 1. A simulated radiation imaging apparatus comprising a table, a model detector, a model radiation generator, a data input means, a threshold value DB, a control means and an alarm means,
The table can be horizontally moved in the width direction and the longitudinal direction as a rectangle, and is capable of measuring a first table movement distance, which is a widthwise movement distance of the table, and a second table movement distance, A distance sensor and a second distance sensor;
The model detector includes a third distance sensor disposed inside the table and horizontally movable in the longitudinal direction of the table and capable of measuring a detector moving distance that the model detector horizontally moves;
The model radiation generator is arranged to be capable of vertical movement in the upper portion of the table and horizontal movement in the width direction and longitudinal direction of the table, and the fourth distance sensor, the fifth distance sensor, the sixth distance sensor, Wherein the fourth distance sensor measures a SID (Source to Image Distance), which is a vertical distance between the model detector and the model radiation generator, and the fifth distance sensor and the sixth distance sensor measure the model radiation And a second tube movement distance that is a longitudinal movement distance, wherein the angle sensor measures a distance between a vertical line on the surface of the model detector and a vertical line on the surface of the model radiation, A first tube angle &thetas;, which is an angle between a center line in the imaginary radiation of the generator, and a line projected on the surface of the model detector, Measuring a second tube angle ([phi]) that is an angle between a center-to-center direction of the width of the detector;
Wherein the data inputting means receives from the operator a photographing condition including a photographing part, a photographing posture, a photographing angle, a tube voltage and a tube current amount;
Wherein the threshold value DB stores an adjustment threshold value for each of the model detector and the model radiation generator according to an imaging condition;
Wherein,
- collecting sensing information from the first distance sensor, the second distance sensor, the third distance sensor, the fourth distance sensor, the fifth distance sensor, the sixth distance sensor, and the angle sensor,
Calculating a distance from the sensing information to a center distance between the central point of the radiation in which the center line of the imaginary radiation meets the surface of the model detector and the center point of the model detector,
- determining an adjustment threshold value in accordance with the shooting condition input from the operator from the threshold value DB and, when at least one of the sensing information or the center distance exceeds the adjustment threshold value, Terminating the process after generating the message; A radiographic imaging device capable of detecting a radiographic error, 3. The image processing apparatus according to claim 1 or 2, further comprising an image data DB, image processing means and display means;
Wherein the image data DB stores radiographic image data photographed for each photographing position by the photographing posture and the photographing angle;
Wherein the control unit controls one of the radiation image data from the image data DB according to the photographing part, the photographing posture, and the photographing angle when the sensing information and the center distance are within the adjustment threshold value, ;
Wherein the image processing means produces an adjustment image for the simulation image according to the tube voltage and the tube current amount and displays the adjustment image on the display means; A radiographic imaging device capable of detecting a radiographic error, 3. The apparatus according to claim 1 or 2, wherein the photographing condition further includes grid information including whether a grid is inserted, a focal length of the grid, a grid width, a grid height, and a grid interval, A radiographic imaging apparatus capable of detecting a radiation imaging error

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