KR102083820B1 - Mammography apparatus and position alingement control method thereof - Google Patents

Abstract

The present invention relates to a mammography apparatus for X-ray imaging of a subject, the apparatus body being movable in a vertical axis direction and rotatable about a first horizontal axis to photograph the subject up and down and in and out of the body; A generator fixed to one end of the apparatus main body to irradiate X-rays; A subject support portion fixed to the other end of the apparatus main body and including a detector facing the generator; A first moving unit for moving the apparatus main body in the vertical axis direction; A rotating unit for rotating the apparatus main body about the first horizontal axis; And a controller for controlling the first moving unit and the rotating unit, wherein the controller rotates the apparatus main body simultaneously with the rotating unit so that the center of the upper surface of the subject support part is positioned on the same horizontal plane. A mammographic apparatus is provided which controls a first moving unit to move the apparatus main body.

Description

MAMMOGRAPHY APPARATUS AND POSITION ALINGEMENT CONTROL METHOD THEREOF}

The present invention relates to a mammography apparatus for x-ray imaging a breast and a method for controlling the position alignment thereof, and more particularly, to a mammography apparatus and its position alignment capable of quickly moving and aligning a test unit to a position that matches a body of a subject. It relates to a control method.

The present invention is derived from the research conducted as part of the development of the nanomaterial-based multi-X source and tomographic image system technology of the Ministry of Knowledge Economy [Task control number: 10037414, Title: Nano-based multi-X source and tomography image system Technology development].

X-ray refers to electromagnetic waves having a short wavelength corresponding to a wavelength of 0.01 nm to 10 nm and a frequency of 30 × 10 ¹⁵ Hz to 30 × 10 ¹⁸ Hz. X-ray imaging is one of radiography that projects and displays the inside of a subject under the high penetrating power of the x-ray. As is well known, X-rays are accompanied by attenuation due to the material, density and thickness of an object, such as compton scattering and photoelectric effects during the transmission of the object. Accordingly, X-ray imaging projects and displays the inside of the subject on a plane based on the amount of attenuation of the accumulated X-ray during the process of passing through the subject.

In recent years, X-ray imaging technology has been combined with the semiconductor sector, and instead of the traditional analog method using film, digital X-ray imaging technology has various advantages such as relatively high resolution, wide dynamic range, easy generation of electrical signals, and simple data processing and storage. Is rapidly evolving. Digital-based imaging technology strongly reflects the clinical and environmental needs of early diagnosis of disease based on the excellent diagnostic capabilities of digital imaging.

Accordingly, by utilizing the inherent biological tissue contrast ability of X-rays, the internal structure of the breast as a subject is expressed in high resolution images, and the breast-only X-ray imaging which can detect lesions and microcalcifications for the detection and early diagnosis of breast cancer Technology "Digital Mammography" is introduced. Such digital mammography is rapidly spreading due to various advantages of digital x-ray imaging technology and the inherent characteristics of minimizing the exposure through image magnification, reducing the number of shots, increasing the resolution, and adjusting the brightness and contrast ratio.

The general mammography apparatus is generally a C-shaped support column having a lower column fixed to the bottom, and an overall C-shaped or installed in such a way that the support column can be elevated in a vertical direction and the middle part is rotatable about a horizontal axis. C-arms or device bodies exhibiting similar shapes. A generator for irradiating X-rays toward the lower end is mounted at the upper end of the apparatus main body, and a detector facing the generator is mounted at the lower end of the apparatus main body. Between the generator and the detector is provided with a pressing pad for linearly reciprocating up and down along the inner surface of the apparatus main body.

In such a mammography apparatus, when the subject enters the sitting position or the sitting position in the photographing position, the apparatus body is lifted and rotated with respect to the supporting column so that the height and angle are adjusted so that the breast of the subject is placed in the desired position on the detector. The compression pad then compresses the breast by moving towards the detector. In this state, the generator irradiates the X-ray toward the breast and the detector, and the detector located behind the breast receives the X-ray passing through the breast to obtain an image.

That is, the detector generates an electric signal for each position in proportion to the incident amount of the X-ray. When the electric signal and the position information are read and processed by an image processing algorithm, the detector may obtain an X-ray image of the breast for the corresponding angle. Then, by repeating the above process while rotating the generator and the detector between the breasts, the mammography apparatus can obtain a high-resolution image of the breast of the subject at various angles of Mediolateral Oblique View (MLO).

In the general mammography apparatus having the above photographing principle, the key driving mechanisms for minimizing the inconvenience of the examinee and obtaining high quality X-ray images are the pressing operation of the compression pad and the lifting and rotating operation of the apparatus body. In particular, the compression pad is directly connected to the pain and discomfort felt by the subject by directly applying pressure to the breast during X-ray imaging, and the device body is directly connected to the quality of the X-ray image as the device body determines the correct photographing position through lifting and rotating.

Here, the purpose of the compression pad to compress the breast is to take a picture in the state in which the breast is pressed in order to separate the cores (parts likely to have lesions or microcalcifications) and the like that overlap with the mammary gland. To accurately detect such lesions or microcalcifications, the breast is usually taken from various angles.

1 to 3 are schematic diagrams showing a standard photographing method of a mammography apparatus, in which FIG. 1 shows a craniocaudal view (CC), and FIGS. 4 is a schematic diagram showing an operation mechanism of a photographing unit of a general mammography.

As shown in Figs. 1 to 3, in the standard mode, CC and MLO imaging are performed on the left and right breasts, respectively. For example, at least three images of the right breast including the RCC and the RMLO are taken, and the left breast is the LCC. And at least three images including LMLO. For this imaging, the imaging unit of the mammography apparatus should rotate at a corresponding angle.

Referring to FIG. 4, in the conventional mammography apparatus, the rotation axis 12a of the apparatus main body 10 provided with the photographing unit is typically eccentrically positioned upward from the center of the apparatus main body 10 due to the center of gravity or the like. . Therefore, the apparatus main body 10 presses the breast BR, which is the subject, between the compression pad 15 and the detector 14 at the position (a) of FIG. 4, so as to perform CC imaging by the generator 13 and the detector 14. Is carried out. Thereafter, for MLO imaging, the apparatus main body 10 is rotated at a desired angle θ as shown in FIG. 4 (b), and then again adjusted to the breast height as shown in FIG. 4 (c). must descend by y. In other words, the apparatus main body 10 performs two-stage operations of rotation and descent.

In the conventional mammography apparatus, the position and angle of the apparatus are manually adjusted according to the body shape (key, breast position, etc.) of the subject during standard imaging, and linear movement and rotation of the apparatus main body are usually controlled separately to provide rapid operation. You won't be able to. For example, as described above, the height of the photographing unit is changed by the rotation of the apparatus main body when the MLO photographing after the CC photographing or when the CC photographing after the MLO photographing. After that, it is necessary to lower or elevate the photographing unit by a height changed by rotation, and the accuracy thereof may be deteriorated. Furthermore, the subject must withdraw from the mammography apparatus to enter and descend the apparatus main body and must enter the photographing position again after height adjustment. For this reason, there is a problem in that the photographing time of the mammography apparatus becomes long, and accordingly, fatigue of the examinee and the inspector is increased. In addition, due to the manual operation it is difficult to obtain a uniform photographing result of the left and right symmetry, there is a problem that the shooting accuracy is lowered.

Accordingly, the present invention has been proposed to solve the above-described problems, and the mam mode is easy to align to the position (key, breast height) of the subject while reducing the device driving time as much as possible when X-ray imaging of various angles It is an object of the present invention to provide a rape device and a method for controlling its position alignment.

According to an aspect of the present invention for achieving the above object, the apparatus main body is movable in the vertical axis direction and rotatable about a first horizontal axis to shoot the subject up and down and internal and external shooting; A generator fixed to one end of the apparatus main body to irradiate X-rays; A subject support portion fixed to the other end of the apparatus main body and including a detector facing the generator; A first moving unit for moving the apparatus main body in the vertical axis direction; A rotating unit for rotating the apparatus main body about the first horizontal axis; And a controller for controlling the first moving unit and the rotating unit, wherein the controller rotates the apparatus main body simultaneously with the rotating unit so that the center of the upper surface of the subject support part is positioned on the same horizontal plane. A mammographic apparatus is provided which controls a first moving unit to move the apparatus main body.

The device body further includes a second moving unit that is movable in a second horizontal axis direction perpendicular to the first horizontal axis, and controlled by the controller and moving the device body in a second horizontal axis direction, wherein the controller is The rotation unit rotates the apparatus main body so as not to move the center of the upper surface of the object support, and the first and second moving units may be controlled to move the apparatus main body in conjunction with the rotation unit.

According to another aspect of the present invention for achieving the above object, a device main body which is movable in the vertical axis direction and rotatable about a first horizontal axis to shoot the subject up and down and internal and external shooting, and at one end of the device main body; And a mammographic apparatus comprising a subject support having a fixed fixed X-ray generator and a detector fixed to the other end of the apparatus main body and facing the generator; There is provided a method of controlling position alignment of a mammography device comprising rotating the device body about a first horizontal axis so as to be located on the same horizontal plane and simultaneously moving the device body in a vertical axis direction.

The apparatus main body is movable in a direction of a second horizontal axis perpendicular to the first horizontal axis, and the step of simultaneously moving and rotating the apparatus main body moves the apparatus main body so that the center of the upper surface of the subject support part does not move. Rotating with respect to the vertical axis and may include the step of moving in the direction of the second horizontal axis.

According to the mammography apparatus of the present invention and its position alignment control method, the rotation and lifting operation of the photographing unit is automatically performed simultaneously with each other during X-ray photographing of various angles, and automatically and simultaneously during the alignment of the photographing unit. By minimizing the movement, the driving and shooting time of the device can be minimized as much as possible. Due to this shortening of time, fatigue and discomfort of the subject and the inspector can be minimized.

In addition, by simultaneously performing the rotation and lifting operation of the imaging unit automatically, it is possible to obtain a uniform photographing result with accurate symmetry, so that lesions, microcalcifications, and the like can be accurately read.

1 to 3 are schematic diagrams showing a standard photographing method of a mammography apparatus, FIG. 1 is a diagram illustrating top and bottom imaging (CC), and FIGS. 2 and 3 are diagrams illustrating internal and external imaging (MLO).
4 is a schematic diagram showing an operation mechanism of a photographing unit of a general mammography.
5 is a perspective view showing the overall configuration of a mammography apparatus according to the present invention.
6 is a perspective view of a portion of an apparatus body and a support column of a mammography apparatus according to the present invention.
7 is a schematic view showing a controller of a mammography apparatus according to the present invention.
8 is a view for explaining the operation of the mammography apparatus according to the present invention.

Further objects, features and advantages of the invention may be more clearly understood from the following detailed description and the accompanying drawings. Prior to the detailed description of the present invention, the present invention may be modified and modified in various ways, and may have various embodiments. The examples described below and shown in the drawings are not intended to limit the invention to the specific embodiments. In addition, it is possible to make various changes, modifications, and modifications within the scope of the following claims, which are also understood to be included within the scope of the invention.

When a component is said to be "connected" or "connected" to another component, it may be directly connected or connected to each other, but indirectly connected or connected by another component intervening. It should be understood to include what is present. On the other hand, when a component is referred to as being "directly connected" or "directly connected" to another component, it should be understood that there is no other component in between.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In this specification, terms such as "comprise" or "have" are intended to indicate that there is a feature, number, step, operation, component, part, or combination thereof described on the specification, one or more other features. It is to be understood that the present disclosure does not exclude the possibility of the presence or the addition of numbers, steps, operations, components, components, or combinations thereof.

In addition, the terms "... unit", "... unit", "... module", and the like described in the specification mean a unit for processing at least one function or operation, which is hardware or software or hardware and It can be implemented in a combination of software.

In addition, in the description with reference to the accompanying drawings, the same components will be given the same reference numerals and redundant description thereof will be omitted. In the following description of the present invention, when it is determined that the detailed description of the related known technology may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

Hereinafter, a digital mammography apparatus according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. In the present specification, the "mammography apparatus" has been described as an example of a digital mammography apparatus, but the present invention is not limited thereto and may be applied to an analog system as well.

Fig. 5 is a perspective view showing the overall configuration of the mammography apparatus according to the present invention, and Fig. 6 is a perspective view of a part of the apparatus body and the support column of the mammography apparatus according to the present invention.

As shown in FIGS. 5 and 6, the mammography apparatus according to the present invention includes a device body 100 including basic components for X-ray imaging, and a support column to which the device body 100 is vertically movable. 200).

The support column 200 has a vertical columnar shape and basically supports the apparatus main body 100. The support column 200 may be configured such that its lower end is mounted to a base rail (not shown) in the x-axis direction in FIG. 5 and is movable along the x-axis. The base rail includes a support column moving unit (not shown), and the support column moving unit can linearly move the support column 200 in the x-axis direction. To this end, the support column moving unit may comprise any one of a first motor and a rack / pinion, a belt, a ball screw as a means for converting rotation of the first motor into linear movement. Such a configuration is well known to those skilled in the art, and a detailed description thereof will be omitted. On the other hand, the support column 200 supports the apparatus main body 100 while providing a vertical axis thereon such that the apparatus main body 100 can be elevated in the vertical longitudinal direction (y-axis direction in FIG. 5). The support column 200 also includes a device body lifting unit for moving the device body 100 (specifically, the support column connection 110 of the device body 100) up and down. The body lifting unit includes means for converting the rotation of the second motor and the second motor into linear movement, which is substantially the same as the supporting column moving unit except for the driving direction.

The device main body 100 is also called a C arm because the upper and lower ends face each other in an arc shape, and thus exhibit a C shape or similar shape as a whole. The apparatus body 100 includes a support column connector 110 connected to the support column 200 in a vertical direction and a vertical connector 120 rotatably connected to the support column connector 110. The apparatus main body 100 is a photographing unit, which is mounted on one end (for example, the upper end in this embodiment) of the vertical connection portion 120 of the apparatus main body 100 and faces the other end (for example, in the present embodiment). A generator 130 for irradiating the X-ray toward the lower end, a detector 140 mounted at the other end of the vertical connection part 120 to face the generator 130, and a generator along the inner surface of the apparatus main body 100. And a plate-shaped pressing pad 150 which linearly reciprocates between the 130 and the detector 140. The subject is positioned between the compression pad 150 and the detector 140 to perform X-ray imaging, but selectively installs the test plate 160 between the compression pad 150 and the detector 140 to press the subject. The X-ray imaging may be performed by being positioned between the pad 150 and the test plate 160. That is, when there is no test plate 160, the detector 140 serves as the test object support, and when there is a test plate 160, the test plate 160 serves as the test object support.

The vertical connection part 120 is connected to the column connection part 110 so as to be rotatable about a horizontal axis (z-axis of FIG. 5) so as to allow the internal and external photographing of the breast, and to rotate the vertical connection part 120 in this way ( A device body rotating unit (not shown) is provided. The device body rotating unit may be composed of a third motor and a series of gear trains, which are also well known to those skilled in the art and a detailed description thereof will be omitted.

The vertical connection part 120 basically consists of pillars connecting the upper and lower ends and the poles on which the generator 130 and the detector 140 are mounted, respectively. The pressing pad 150 is slidably mounted on the column of the vertical connection part 120, and driving means for moving the pressing pad 150 up and down is provided at one side of the vertical connection part 120. This vertical movement of the compression pad support 152 and the compression pad 150 connected thereto presses the breasts positioned on the detector 140 or, optionally, on the test plate 160.

The generator 130 mounted on the upper end of the apparatus main body 100 generates an x-ray by colliding electrons having high kinetic energy with a target of metal. Preferably, the generator 130 controls an irradiation direction or an irradiation area of the x-ray. Optical systems, such as a collimator, are provided.

The detector 140 mounted on the lower end of the apparatus main body 100 is basically a means for receiving an X-ray passing through the breast to obtain an image. The detector 140 may also serve as a support for supporting a body by placing the breast on it. . That is, the breast is pressed between the detector 140 and the compression pad 150 by pressing the breast with the compression pad 150 after placing the breast on the detector 140. The breast of the patient is photographed by the generator 130 and the detector 140. The detector 140 may generate an electrical signal for each position in proportion to the incident amount of the X-ray, and may read the electrical signal and the position information and process the same by an image processing algorithm to obtain an X-ray image of the breast. At this time, the detector 140 has a direct conversion method for obtaining an electrical signal directly from the X-ray without an intermediate step according to the conversion method of the X-ray, or indirect conversion for converting the X-ray into visible light to obtain an electrical signal indirectly by the visible light. General technical content such as method can be widely applied.

The test plate 160 may be included as an optional configuration in order to replace the function of the detector 140 as a test subject support. When the test plate 160 is included, the breast is pressed by the compression pad 150 and the test plate 160, and the breast in this state is photographed through the generator 130 and the detector 140. Therefore, the detector 140 performs only a function of receiving an X-ray passing through the breast to obtain an image.

The mammography apparatus configured as described above further includes a controller 300 of FIG. 7 for controlling linear movement and rotation of the apparatus main body 100. The controller 300 is a component for controlling all components of the mammography apparatus, and functions other than the function of controlling the linear movement and rotation of the apparatus main body 100 are the same as those of the conventional mammography apparatus. That is, the function of controlling the linear movement and rotation of the apparatus main body 100 may be functionally added to the controller of the previously installed mammography apparatus. Alternatively, the controller 300 may be provided in the form of a sub-controller to control only linear movement and rotation of the apparatus main body 100 and other components of the mammography apparatus may be controlled in a separate main controller. In this specification, in any case, the controller 300 will only describe a function of controlling the linear movement and rotation of the apparatus main body 100.

The controller 300 includes a mode selector 320, a torque determiner 340, and first to third motor controllers 361, 362, and 363. The mode selector 320 selects a subsequent mode, that is, a photographing angle in the case of a CC photographing mode, an MLO photographing mode, and an MLO photographing mode according to an external command. The torque determiner 340 calculates the rotational force of the first to third motors (using the relationship shown in FIG. 8 to be described below) according to the selection mode of the mode selector 320. The first to third motor controllers 361, 362, and 363 respectively control the first to third motors based on the calculated rotational force of the motors, so that the x-axis of the photographing unit provided in the apparatus main body 100 and Control linear movement in the y-axis direction and rotational movement in the z-axis direction.

The controller 300 may include first and second motors for linear movement in the x-axis and y-axis directions of the imaging unit included in the apparatus main body 100, and a third motor for rotation in the z-axis direction of the imaging unit. By interlocking, it may be controlled to simultaneously perform the movement, lifting, and rotating of the apparatus main body 100 in the x-axis direction.

With reference to FIG. 8, the linear movement and rotation operation of the imaging units by the said 1st-3rd motor are demonstrated. 8 is a view for explaining the operation of the mammography apparatus according to the present invention.

Since the subject is positioned on the upper surface of the subject support unit 140 or 160, the linear movement distance due to the rotation of the imaging unit is preferably controlled based on the center of the upper surface of the subject support unit 140 or 160. . When the apparatus main body 100 rotates (counterclockwise) about the z axis by the angle θ, the subject support portion 140 or 160 moves linearly by a in the x-axis direction and linearly by b in the y-axis direction. do. Therefore, when the apparatus main body 100 is rotated by θ and moved at the same time in the -x axis direction (left) by a and in the -y axis direction (downward) by b, the upper portion of the subject support part 140 or 160 The center of the plane does not move in the x- and y-axis directions, but has an orientation in which the upper surface of the subject support portion is rotated by θ. That is, the subject supporter 140 or 160 may always maintain a constant x-axis position and y-axis position (ie, height). At this time, assuming that the distance from the rotational axis of the apparatus main body 100 to the upper surface of the subject support part 140 or 160 is A, the values of a and b are as follows.

a = A * sinθ

b = A-A * cosθ = A (1-cosθ)

Therefore, by rotating the apparatus main body 100 by θ and simultaneously moving it left and downward in conjunction with it by A * sinθ and A (1-cosθ), the subject support portion 140 or 160 is centered on its upper surface. You can keep this initial position.

According to the above relationship, the controller 300 determines the rotational force of the first to third motors corresponding to the movement distances a and b and the rotation angle θ in the torque determination unit 340. Subsequently, the first to third motor controllers 361, 362, and 363 receive the determined rotational force data, and simultaneously interlock the first to third motors based on the determined rotational force data, so that the x and y axis directions of the apparatus main body 100 are provided. Perform linear movement and rotation at the same time. At this time, the linear movement and rotation of the apparatus main body 100 in the x-axis and y-axis directions are performed by the movement of the supporting column 200 by the supporting column moving unit, the movement of the apparatus main body 100 by the main body lifting unit, and the apparatus main body, respectively. It can be made by the rotation of the device body 100 by the rotating unit.

As such, even if the apparatus main body 100 rotates by θ, the center of the upper surface of the subject support portion 140 or 160 can maintain the initial position as it is, so that the mammography apparatus according to the present invention does not require the subject to move in particular. X-ray imaging can be performed at various angles. That is, each time the conventional mammography apparatus changes the photographing angle, the subject withdraws behind the mammography apparatus, and when the apparatus is set to the corresponding orientation state, the subject does not need to move, compared to having to enter the mammography apparatus again. The mammography apparatus of the present invention can significantly shorten the imaging time, which is very efficient and can reduce the fatigue applied to both the subject and the inspector.

Meanwhile, in the above embodiment, the support column 200 to which the apparatus body 100 is moved is moved in order to move the apparatus main body 100 in the x-axis direction, but the support column 200 is fixed to the bottom and is perpendicular to the support column connection unit 110. An x-axis movement of the apparatus main body 100 may be implemented by adding a stage movable in the x-axis direction to any portion therebetween, including the connector 120. Alternatively, the support column 200 may be fixed to the floor, and an examinee stage movable in the x-axis direction may be added to the front of the apparatus main body 100, and the examinee may be positioned in a standing or sitting position on the examinee stage. The subject stage should move by a in the x-axis direction (right side) rather than the -x-axis direction (left side) when the rotation described in connection with FIG. 8 is performed. Care must be taken.

As another embodiment of the mammography apparatus of the present invention, the support column 200 is fixedly installed on the floor so that the apparatus main body 100 cannot move in the x-axis direction and at the same time, the x-axis direction of the apparatus main body 100. Components related to movement, that is, the first motor, the first motor controller, and the like may be removed. In this case, the controller 300 includes a second motor for linearly moving in the y-axis direction of the device main body 100 provided in the device main body 100 and z of the device main body 100 provided in the device main body 100. Only the third motor for the rotation in the axial direction can be controlled to perform the lifting and rotating operation of the apparatus main body 100 at the same time. Accordingly, when the apparatus main body 100 is rotated by θ and moved downward by A (1-cosθ), the subject support part 140 or 160 is y even though the center of its upper surface is moved in the x-axis direction. There is no axial movement to maintain a constant height. Since the mammography apparatus having such a configuration only needs to move to the right side (or left side), compared to the mammography apparatus according to the prior art, it is possible to considerably shorten the shooting time, which is very efficient and the fatigue applied to both the subject and the inspector. Can be reduced. This requires the movement of the subject somewhat, but has the advantage that the device is simpler and thus the cost can be reduced compared to the above-described embodiment.

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and various substitutions, modifications, and changes are possible in the art without departing from the spirit of the present invention. It will be apparent to those who have the knowledge of.

100: device body 110: support column connection
120: vertical connection portion 130: generator
140: detector 150: pressure pad
200: support column 300: controller
320: mode selector 340: torque determiner
361: first motor control unit 362: second motor control unit
363: third motor control unit

Claims (4)

An apparatus main body which is movable along a vertical axis and rotatable about a first horizontal axis, capable of capturing the subject up and down and in and out of the body;
A generator fixed to one end of the apparatus main body to irradiate X-rays;
A support for a subject secured to the other end of the device body and including a detector facing the generator, the support comprising a top surface having a center at an initial position;
A first moving unit for moving the apparatus main body along the vertical axis;
A rotating unit for rotating the apparatus main body about the first horizontal axis; And
A controller for controlling the first moving unit and the rotating unit;
The controller is configured to rotate the apparatus main body while maintaining the center of the upper surface of the support portion in the initial position, and simultaneously with the rotation of the apparatus main body, the first moving unit moves the apparatus main body. Controlled to move along the vertical axis
Mammography device.
The method of claim 1,
A second moving unit for moving the apparatus main body along a second horizontal axis perpendicular to the first horizontal axis,
The apparatus main body is movable along the second horizontal axis, the second moving unit is controlled by the controller,
The controller may be configured such that the rotating unit rotates the apparatus main body about the first horizontal axis so that the center of the upper surface of the support for the subject does not move, and the first and To control the second mobile unit to move the apparatus main body.
Mammography device.
A device main body which is movable along a vertical axis and rotatable about a first horizontal axis, capable of photographing a subject up and down and internally and externally, a generator fixed to one end of the device main body to irradiate X-rays, and And a mammographic apparatus comprising a support for a subject having a detector fixed to the other end and having a detector facing the generator, wherein the support comprises a top surface having a center in an initial position. Include steps,
Rotating the device body about a first horizontal axis to maintain the center of the upper surface of the support at the initial position and simultaneously moving the device body along a vertical axis in conjunction with rotation of the device body;
How to control the position alignment of a mammography device.
The method of claim 3,
The device body is movable along a second horizontal axis perpendicular to the first horizontal axis,
Rotating the device body about a first horizontal axis and simultaneously moving the device body along a vertical axis in conjunction with the rotation of the device body may prevent the center of the upper surface of the support for the subject from moving. Rotating the device body about a first horizontal axis and moving the device body along the vertical axis and the second horizontal axis in conjunction with rotation of the device body;
How to control the position alignment of a mammography device.

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