KR101531370B1 - X-ray Imaging Device And Imaging Method Thereof - Google Patents

Abstract

The present invention includes an x-ray generator for generating an x-ray beam and a narrow-width detector for receiving the x-ray beam and generating projection data for a region of interest as a part of the object, An imaging apparatus and imaging method of an X-ray imaging apparatus are disclosed.
According to the present invention, it is possible to minimize the cost of an x-ray imaging apparatus because a cross-sectional image can be obtained for as wide a range of a necessary object as possible using a narrow detector without using a large and expensive detector, Can be minimized. Also, according to the present invention, the artificial shadow can be minimized and the image reconstruction procedure can be simplified, so that the time required for data processing can be shortened.

Description

[0001] DESCRIPTION [0002] X-ray Imaging Device and Imaging Method Thereof [0003]

The present invention relates to an imaging method of an X-ray imaging apparatus for acquiring an image of a subject using an X-ray and to an X-ray imaging apparatus therefor. More particularly, Ray imaging apparatus capable of obtaining a cross-sectional image and / or a three-dimensional image having a wider area of interest than the detector using a detector having a small width, and an X-ray imaging apparatus therefor.

An X-ray imaging apparatus, that is, an X-ray imaging apparatus, uses a characteristic that an intensity of an X-ray is attenuated depending on a physical property and a distance of an object when an X-ray passes through the object, And images it. For example, when an X-ray is irradiated to a person, a projection image of the inside of the body can be obtained by using an X-ray attenuation coefficient varying depending on the type and characteristics of a living tissue.

An X-ray computed tomography imaging device, which is an example of the X-ray imaging apparatus, includes an X-ray generator for irradiating the X-ray to the subject so that the X-ray penetrates the object and an X- Detector. Generally, the X-ray generator and the detector are provided in an arm supporting the X-ray generator and the detector, and acquire image information of the object while rotating around the object in a state facing each other.

In the above-described X-ray CT imaging apparatus, the cross-sectional image of the subject can be generated by irradiating the subject with X-rays at various angles to obtain projection data and reconstructing the cross-sectional image from the projection data.

3D CBCT (Cone Beam Computed Tomography) technology has already been introduced into dental imaging and mammography, where the detector is large enough to cover the entire imaging area, particularly the region of interest Or has an excessive size. However, in the case of 3 - dimensional CBCT, the radiation exposure to the patient is severe, and the use of a detector of a large size has a problem that it is a burden on a small - sized dental hospital due to a cost problem.

In radiology, the Panoramic Imaging Technique has been used to acquire images of all teeth and their surrounding structures at one time. A 2-dimensional panoramic image shows a predetermined curved structure along a patient's jaw, and a panoramic imaging device is widely used for diagnosis for a dental procedure because of its relatively low price.

In the above-described panoramic imaging technique, the X-ray generator and the detector are mounted on the arm and fixed to the opposite sides. The arm is mounted on a moving means, and the moving means causes the arm to move along a predetermined orbit around the subject to be imaged.

1, the conventional panoramic imaging apparatus includes an X-ray generator 10 and a detector 20, which are spaced apart from each other by a predetermined distance, and the X-ray generator 10 and the detector 20, Obtains projection data for the object while rotating around the object 1, and the projection data is reconstructed into a section of the object to obtain a sectional image. Here, the width W of the detector 20 is such that the X-ray beam 10a covering the entire object, particularly the entire region of interest, can be incident.

On the other hand, it is necessary to acquire three-dimensional information (3D Information) or cross-sectional slice for a small region of the object to be imaged (an object), such as a hard tissue (alveolar bone) check between dental teeth or a dental implant procedure There is a case. The above-mentioned three-dimensional information can be easily obtained by using a dental CBCT apparatus, but in the case of a small-sized dentist, there is not enough capacity to purchase and hold it. Further, using a wide detector and a wide x-ray beam 10a, such as a CBCT device, used to acquire a three-dimensional image of the patient's head to acquire a smaller three-dimensional image would require the patient to acquire an enormous amount of radiation To the outside.

2 shows a conventional example using a detector 20 having a width of a size large enough to cover the projection of the entire region of interest 2 and the x-ray beam of the same size as the region of interest 2 for which the image information is required. Of a single-layer imaging technique.

2, the X-ray generator 10 is disposed on one side of the subject 1 or the region of interest 2, and the detector 20 is disposed on the other side. The X-ray generated by the X-ray generator 10 is transmitted through the region of interest 2 and detected by the detector 20 on the opposite side.

More specifically, the X-ray generator 10 and the detector 20 are mounted on a suspension arm of the imaging apparatus so as to be positioned on the opposite sides of the X-ray generator 10 and the detector 20, . The projection data for the region of interest may be obtained at various angles and image information of the region of interest, such as cross-sectional slices, may be obtained through a reconstruction technique.

FIGS. 3A and 3B relate to conventional Tomosynthesis image acquisition. When the X-ray generator 10 and the detector 20 are moved at the same speed and at the same time in opposite directions to each other, ) Appear sharp, while the distant area appears dim.

The tomosynthesis is a method in which the x-ray generator and the detector move the object at a limited photographing angle, typically 20 to 60 degrees, along a parallel plane or circular orbit as shown in Fig. 3a or 3b, Acquires a slice image from the projection data, and reconstructs a three-dimensional image through a reconstruction algorithm.

However, since the above-described imaging method of the conventional X-ray imaging apparatus or X-ray imaging apparatus, that is, the image acquisition method, requires a large-sized expensive detector and exposes the patient to a large amount of radiation, The problem becomes.

Korean Patent Laid-Open Publication No. 10-2012-0140102, December 28, 2012 United States Published Patent Application No. 2009/0041178 A1, February 12, 2009

It is an object of the present invention to provide an imaging method of an x-ray imaging apparatus capable of acquiring image information (a cross-section image or a three-dimensional image) of a region of interest using a detector that is narrow and difficult to cover the entire region of interest with a single detector Ray imaging device.

An imaging method according to the present invention is to provide an imaging method of an X-ray imaging apparatus and an X-ray imaging apparatus for acquiring a plurality of partial projection data of a part of a region of interest while moving along a predetermined orbit and effectively reconstructing image information of a region of interest will be.

The present invention includes an x-ray generator for generating an x-ray beam and a narrow-width detector for receiving the x-ray beam and generating projection data for a region of interest as a part of the object, And a method of imaging an X-ray imaging apparatus.

One aspect of the present invention is directed to a method for acquiring a plurality of partial projection data for a region of interest in which image information is required as a part of a subject by moving the detector and a rotating X- (A) scanning the whole; And (b) reconstructing an image of the region of interest using the plurality of partial projection data (Sub-projection Data) to obtain image information of the region of interest. .

In the step (b), an image of the ROI is reconstructed using partial projection data that does not have overlapping data among the plurality of projection data and divides the entire ROI into a plurality of partial projection data.

In the step (a), the entire region of interest is scanned in a plurality of different directions, and a plurality of partial projection images for the ROI are obtained for each direction.

In addition, the step (a) may include: Scanning the entire region of interest in either direction of the region of interest through rotational and translational motion of the support unit in which the x-ray generator and the detector are mounted opposite to each other.

More specifically, the step (a) comprises: Wherein when the angle of the x-ray beam incident on the detector is θ and the support unit moves from the first position to the second position for scanning the entire region of interest in either direction of the region of interest, one time, the center of rotation _{(C 'x, C' y} ) and the position _{(S 'x, S' y} ) of the x-ray generator for the x-ray generator and the detector, respectively (T _x + τv _x, T _y + τv _y) And (S _x +? V _x , S _y +? V _y ).

(C _x , C _y ) and the position of the _x- ray generator is (S _x , S _y ) at the first position, and the line connecting the x-ray generator and the detector and the rotation center of the support unit (C _x , C _y ) rotated by θ around (S _x , S _y ) is called (T _x , T _y ); (C _x called, C _y), and focusing on the (M _x, M _y) in the (T _x, T _y), and; (v _x, v _y) is connecting the (M _x, M _y), and (S _x, S _y) the vector; τ represents the moving distance of (T _x, T _y) the vector (v _x, v _y) is moved in a direction (T _x, T _y) for the matching to the line (ℓ))

In the step (b), the image of the ROI includes one of a 3D image and a cross-sectional image of the ROI.

In this case, the step (b) And inputting a plurality of partial projection data for the ROI as input data of the RO reconstruction algorithm to reconstruct an image of the ROI.

In another aspect, the present invention provides a support unit comprising: a support unit capable of translational motion and rotational motion; An image capturing unit having an X-ray generator provided at one side of the support unit for emitting X-rays and a detector provided at the other side of the support unit so as to move in a state facing the X-ray generator;

Wherein the X-ray generator and the detector move in a mutually facing state to capture a plurality of partial projection data for the region of interest, A control unit for controlling movement of the support unit to scan the entire area; And a reconstruction unit for reconstructing an image of the ROI using a plurality of partial projection data for the ROI.

The control unit comprising: Wherein the angle of the x-ray beam incident on the detector is &thetas; and the support unit moves from the first position to the second position for scanning the entire region of interest in either direction of the region of interest, (C _x , C _y ) of the x-ray generator and detector and the positions (S _x , S _{y y} ) of the x-ray generator are (T _x + τv _x , T _y + τv _y ) (S _x +? V _x , S _y +? V _y ).

(C _x , C _y ) and the position of the _x- ray generator is (S _x , S _y ) at the first position, the line (k) connecting the x- (T _x , T _y ), which is rotated about θ by (C _x , C _y ) about (S _x , S _y ), is an angle formed by a line (l) ; (C _x, C _y) and as the midpoint of _{(T x, T y) (} M x, M y) , and; (v _x, v _y) are (M _x, M _y), and (S _x, S _y) the connecting vector is; τ is (T _x, T _y) the vector (v _x, v _y) is moved in a direction indicating a moving distance of (T _x, T _y) for the matching to the line (ℓ) )

More specifically, the control unit comprises: And controls the movement of the supporter unit such that the image capturing unit scans the entire region of interest in a plurality of different directions to acquire a plurality of partial projection images for the region of interest each in one direction.

The reconstruction unit reconstructs an image of the ROI using partial projection data that does not have overlapping data among the plurality of projection data and divides the entire ROI into a plurality of partial projection data.

The imaging method of the x-ray imaging apparatus comprises: A panoramic imaging device can be applied, and it can be applied to other X-ray imaging devices such as a C-arm X-ray device and a Mammography imaging device.

As described above, the present invention provides an image reconstructor, i.e., a reconstruction unit, for reconstructing an image of a region of interest from projection data acquired by an x-ray generator and a detector, the image reconstructor comprising an iterative method, It is possible to reconstruct an image of a region of interest using a block repetitive reconstruction technique such as an OSC algorithm.

According to the present invention, it is possible to obtain a sectional image or a three-dimensional image of a region of interest, that is, a region in which image information is required, by using a low-cost narrow detector instead of a large and expensive detector, And minimize the exposure of the patient to radiation, and the penetration rate of the x-ray imaging device can be greatly extended to a small-scale dental hospital.

According to the present invention, the artificial shadow can be minimized and the image reconstruction procedure can be simplified, so that the time required for data processing can be shortened.

According to the present invention, an image can be obtained for any region of interest in a subject without placing the region of interest at the center of rotation of the x-ray generator and detector, and a three-dimensional Conventional x-ray imaging devices such as a panorama device and a C-arm device can be used as they are when an image or a sectional image is required.

1 is a view showing a general x-ray imaging system.
2 is a diagram illustrating a conventional imaging method of a tomographic imaging technique using a wide detector.
3A and 3B illustrate a conventional tomosynthesis image acquiring process.
4 is a side view showing an embodiment of an X-ray imaging apparatus to which an imaging method of an X-ray imaging apparatus according to the present invention is applied.
FIG. 5 is a schematic plan view of the X-ray imaging apparatus shown in FIG.
FIGS. 6A and 6B are diagrams illustrating the principle of an imaging method of an X-ray imaging apparatus that scans the entire region of interest using a narrow detector and acquires a plurality of partial projection data.
6C is a diagram showing a method of deriving the rotation angle and the linear movement amount (translational movement distance) of the detector in the present invention.
FIG. 7 is a view showing an example of photographing a region of interest with a width that can not cover the whole by one detector using a narrow detector based on the X-ray imaging apparatus and imaging method according to the present invention.
FIG. 8 is a diagram illustrating an example of photographing a molar region of the jawbone, which is a region of interest, based on the X-ray imaging apparatus and the imaging method according to the present invention.
FIG. 9 is a diagram illustrating an example of photographing an incisor region of the jawbone, which is a region of interest, based on the X-ray imaging apparatus and the imaging method according to the present invention.
FIG. 10 is a view illustrating an example of photographing a pre-mental region of the jawbone, which is an area of interest of the present invention, in a fast scanning mode than the position shown in FIG.
11A and 11B are diagrams showing coverage angles of a prefix area and a transposition area, respectively, in the present invention.
12 is a diagram showing an example of classifying (grouping) partial projection data in the present invention.
13A and 13B are diagrams illustrating a method of selecting partial projection data for reconstruction from a plurality of partial projection data obtained in a continuous scanning mode.
14 is a table showing a method of selecting partial projection data for reconstruction of the projection image from the partial projection data obtained in the continuous scanning mode.
15 is a flowchart schematically illustrating a processing procedure of an imaging method of an X-ray imaging apparatus according to the present invention.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, preferred embodiments of the present invention in which the object of the present invention can be specifically realized will be described with reference to the accompanying drawings. In describing the present embodiment, the same designations and the same reference numerals are used for the same components, and additional description thereof will be omitted in the following.

First, an embodiment of an X-ray imaging apparatus capable of implementing an imaging method of an X-ray imaging apparatus according to the present invention will be described with reference to FIGS. 4 and 5. FIG. 4 is a side view showing an embodiment of the X-ray imaging apparatus to which the imaging method of the X-ray imaging apparatus according to the present invention is applied, and FIG. 5 is a schematic plan view of the X-ray imaging apparatus shown in FIG.

4 and 5, an embodiment of an X-ray imaging apparatus to which an imaging method of an X-ray imaging apparatus according to the present invention is applied, that is, an X-ray imaging apparatus for imaging an X-ray imaging apparatus according to the present invention, A control unit 130 and a reconstruction unit 140. The control unit 130 includes a support unit 110 and a video capture unit 121 and 122 provided in the support unit.

The support unit 110 is configured to be able to perform rotational and translational movements. In this embodiment, rotational motion of the degree of freedom 1 and translational movement (linear movement) of the degree of freedom 1 are possible, but the degree of freedom of the support unit 110 is limited And the rotation center of the support unit 110 is on the axis of rotation Axis of the support unit 110. [

The support unit 110 is linearly movable along the longitudinal direction of the guide arm 150 and rotates around a rotation axis perpendicular to the longitudinal direction of the guide arm 150. In this embodiment, the guide arm 150 is provided horizontally long in the frame 160 of the apparatus main body to prevent interference between the support unit 110 and the frame 160, A column supporting the vertical load, and a horizontal bar extending in the form of a cantilever at the upper end of the column, but the shape is not limited thereto.

In order to rotate the support unit 110, an X-ray imaging apparatus according to the present invention is provided with a rotation actuator 111 and a linear actuator 112. Rotary motion and translational motion, like the support unit 11 of the present invention, The technology for realizing a possible device is a general technique in the field of machinery, so that further explanation is omitted.

The image capturing unit includes an X-ray generator 121 and a detector 122. The X-ray detector 121 is provided in the support unit 110 and emits an X-ray beam toward the detector 122, and the detector 122 detects the X- (110).

More specifically, the X-ray generator 121 is installed on one side (one end) of the support unit 110 and the detector 122 is provided on the other side (the other end) of the support unit 110, When the support unit 110 rotates, the X-ray generator 121 and the detector 122 rotate about the periphery of the subject P, particularly around the region of interest, in a state where the X-ray generator 121 and the detector 122 face each other. Therefore, the X-ray imaging apparatus disclosed in this embodiment basically has the structure of the panorama imaging apparatus, but the imaging method of the X-ray imaging apparatus according to the present invention is not limited to the above-described panorama imaging apparatus, (Mammography) imaging device, and the like.

Accordingly, when image information (a three-dimensional image, a cross-section image, or the like) for a region of interest larger than a region that can be photographed at a time is required by using the detector 122, an X-ray imaging apparatus having a large- So that it is possible to obtain a necessary image without the need.

Next, the control unit 130 moves the support unit 110 so that the X-ray generator 121 and the detector 122 scan the entire region of interest while rotating around the ROI in a state in which the X- . More specifically, the image capturing unit 120 photographs a region of interest having a size wider than that of the image capturing unit 120, particularly the detector 122, which is wider than the region that can be captured at one time, The control unit controls the motion of the support unit 110 to obtain a partial projection image. The reconstruction unit 140 reconstructs an image of the ROI using a plurality of partial projection data for the ROI.

6B and 6C, the control unit 130 determines that the angle of view of the detector 122 is θ and the angle of the X-ray beam incident on the detector is θ, When the support unit (110) moves from a first position to a second position to scan the region of interest in either direction and the rotational movement angle of the detector is?, The rotation center of the x- _{(C 'x, C' y} ) each position _{(S 'x, S' y} ) of the x-ray generator (T _x + τv _x, T _y + τv _y) and (S _x + τv _x, S _y + gt _; v _< / RTI > _y ).

At this time, the rotation center of the support unit at the first position is (C _x , C _y ) and the position of the _x- ray generator is (S _x , S _y ); An angle formed by a line connecting the X-ray generator and the detector and a line (l) moving the rotation center of the support unit is? (T _x , T _y ) around a point (S _x , S _y ) rotated by θ by (C _x , C _y ); (M _x , M _y ) of the points (C _x , C _y ) and (T _x , T _y ); (v _x , v _y ) is a vector connecting (M _x , M _y ) and (S _x , S _y ); τ denotes the movement distance of (T _x, T _y) the vector (v _x, v _y) is moved in a direction (T _x, T _y) for the matching to the line (ℓ).

The control unit 130 repeatedly scans the image capturing units 121 and 122 in order to sequentially scan the region of interest in different directions to generate a plurality of partial projection data ) Of the supporter unit (110). Thus, one group of projection image sets can be obtained in either direction of the region of interest, and the projection image set of one group includes a plurality of projection data, and the region of interest is scanned in different directions So that a plurality of groups of projection image sets are obtained. At this time, as the angle between the direction in which the scan is started and the direction in which the scan is terminated is larger when the ROI is scanned, accurate reconstruction of the ROI can be performed. At this time, one group of projection image sets is obtained for each direction.

The reconstruction unit is configured to reconstruct the partial projection data obtained every time the rotation angle of the detector is in the angle of theta by using the partial projection data having mutually neighboring partial projection data, And reconstructs the image of the region to obtain a cross-sectional image, a longitudinal sectional image or a three-dimensional image (volume data).

A collimator 123 is provided on one side of the X-ray generator 121, that is, on the X-ray emitting side, for limiting the width of the X-ray beam incident on the detector 122 to be less than or equal to the width of the detector 122. According to the present invention, the image photographing apparatus captures a plurality of partial projection data by photographing a region of interest larger than an area that can be photographed at one time in a partial shot, reconstructs the image of the region of interest as input data of the reconstruction algorithm, Therefore, it is possible to avoid the use of expensive expensive detectors and to minimize the radiation dose to the patient.

Therefore, the imaging method of the X-ray imaging apparatus described below can be applied to an imaging method capable of reducing the width of the detector 121 or a detector having a width narrower than the area of interest (for example, 50 to 60 mm or 48 mm (2) for obtaining a plurality of partial projection data for a region of interest (2) in which image information is required, of the internal region of the object (P), wherein the perimeter of the region of interest (A) scanning the entire region of interest by moving the X-ray generator 121 and the detector 122, which rotate in opposite directions with respect to each other, to obtain image information of the region of interest 2; (B) reconstructing an image of the ROI using projection data (Sub-projection data).

As described in one embodiment of the X-ray imaging apparatus described above, when the angle of view of the detector 122, more specifically, the angle of the X-ray beam incident on the detector 122 is?, The support unit 110, , Partial projection data obtained each time the rotation angle of the detector is?, I.e., partial projection data having no neighboring but overlapping data, is used to reconstruct the image of the region of interest So that the reconfiguration processing speed can be increased and the data throughput can be reduced.

The step (a) is characterized by scanning the region of interest (2) in a plurality of different directions to acquire a plurality of groups of projection image sets each having a plurality of partial projection data. More specifically, the entire region of interest is sequentially scanned in various directions with a certain angle difference, and a plurality of partial projection data is obtained in each direction.

In the step (a), the entire region of interest is scanned through rotational movement and translational movement (linear movement) of the support unit 110 on which the X-ray generator 121 and the detector 122 are mounted, The rotational and translational motions of the support unit 110 are at least degrees of freedom 1, respectively.

Wherein the step (a) comprises moving the support unit from a first position to a second position for scanning the entire region of interest in one direction of the region of interest and the view angle of the detector is &thetas; when the angle θ, the rotational center _{(C 'x, C' y} ) and the position _{(S 'x, S' y} ) of the x-ray generator for the x-ray generator and the detector, respectively (T _x + τv _x, T _y + τv _y ) and (S _x + τv _x , S _y + τv _y ), and the details of this operation will be described later.

6A and 6B are views for explaining the imaging method of an X-ray imaging apparatus according to the present invention, that is, the principle of image acquisition for a region of interest.

In the image reconstruction using a projection image set obtained by grouping a plurality of partial projection data, artificial shading is prevented from appearing, and at the same time, a narrower detector 122 is used, An ideal method for acquiring an image for the subject 2 is to acquire a partial projection image sequentially while rotating the X-ray generator and the detector as shown in FIG. 6A. In this case, Is the closest mechanism to acquiring an image using a wide detector that can capture the entire region of interest 2 at a time. However, the image acquisition mechanism shown in FIG. 6A is hardly realized by the X-ray imaging apparatus of FIG. 5 or the general panorama apparatus.

In the present invention, as shown in FIG. 6B, in order that the two neighboring partial projection data (Sub-projection data) do not have overlapping portions and the projection data of the entire region of interest is obtained with a minimum number of partial projection data, , I.e., the movement of the suspension arm is controlled. As shown in FIG. 6B, in the stop and shoot mode (the operation mode in which the suspension arm acquires the partial projection data for a part of the ROI and then moves to the next stage to photograph another part), the partial projection data The manner of eliminating the overlap can minimize unnecessary and harmful exposure of the patient to radiation.

Referring to FIG. 6B, the physical rotation center (rotation axis of the support unit) is always positioned on the guide arm 150 while the support unit 110 is moving. Therefore, the projection image set obtained by the imaging method of the X-ray imaging apparatus according to the present invention is different from the method shown in FIG. 6A, and is referred to as an irregular projection image or irregular projection data.

As described above, in this embodiment, since the rotation axis of the support unit 110 is always located in the guide arm 150, the X-ray generator 120 and the detector 122, together with the detector 122, So that the position of the optical fiber 110 also changes. In FIG. 6B, reference symbol S denotes the movement of the X-ray generator, and reference symbol D denotes the movement of the detector.

Hereinafter, with reference to FIG. 6C, a method of obtaining the linear movement amount and the rotational movement angle when the support unit 110 moves from an arbitrary position (first position) to the next position (second position) do.

The rotation center of the support unit 110 is mounted at the position of (C _x , C _y ) at the first position and the position of the _x- ray generator 121 is (S _x , S _y ) (The angle formed by the line K connecting the center of the x-ray generator and the center of the linear movement of the rotation center and the line l moving the center of rotation of the support unit) (Angle of view of the detector) of the x-ray beam incident on the detector 122 is?, The second position of the support unit can be obtained in the following order.

Step 1: Display la around the _{(S x, S y) (} C x, C y) to the new location (T _x, T _y) of the to rotate by _{θ (C x, C y)} .

Step 2: Compute the midpoints of (C _x , C _y ) and (T _x , T _y ) and call this point (M _x , M _y ).

Step 3: Find a vector (v _x , v _y ) connecting (M _x , M _y ) and (S _x , S _y )

Step 4: vector (v _x, v _y) direction as a movement amount _{τ ((T x, T y} ) the vector (v _x, v _y) when moved in a direction in which to place the line _{(ℓ) (T x, T} y ) Is calculated. τ = - (T _x / v _x )

_{Step 5: (T x, T} y) , and (S _x, S _y) the vector (v _x, v _y) direction by τ by linear motion, rotation, the new position (C _'x of the center of the support unit, and C of ' _y ) and the new coordinates (S' _x , S ' _y ) of the _x- ray generator.

Accordingly, _{(C 'x, C' y} ) = (T x + τv x, T y + τv y) _{and, (S 'x, S'} y) = (S x + τv x, S y + τv y) And the angle formed between the support unit 110 and the guide arm 150 at the second position is (? -?).

FIG. 7 shows an example of an X-ray imaging method according to the present invention. The present invention controls the support unit to move along the trajectory described above so that a plurality of groups of irregularly projected images 210,220 and 230 for a region of interest 2, Can be obtained.

That is, the interior of the region of interest 2 is obtained as a whole with a plurality of groups of irregularly projected images, while the outside of the region of interest is imperfectly acquired. At this time, the irregularly projected images can increase the accuracy of the cross-sectional image at various angles, depending on the scanning time and the requirement of the amount of radiation passing through the area of interest and the accuracy of the reconstruction.

Next, FIGS. 8 and 9 show examples of acquiring images of the jawbone posterior region and the transitional region, which are the region of interest 2, using the present invention, wherein the irregularly projected images 210, 220, Are obtained in different directions. More specifically, a panoramic image of the posterior region of the patient is obtained at various angles. The panoramic image and the cross-sectional slices obtained by the imaging method of the X-ray imaging apparatus according to the present invention can greatly enhance the visibility of the internal structure of the ROI. And, useful cross-section sections can be obtained by using only a plurality of groups of projection image sets (irregular projection images). In the case where the subject (patient's head) is located as shown in Figs. 8 and 9, the scanning time in the transitional area is shorter than the scanning time in the posterior area shown in Fig.

Thus, when the subject is located as shown in FIG. 10, a fast scan mode, which is applied to quickly acquire the image (projection image set) of the pre-region, can be used to acquire image information for the posterior region, The reason for the scan mode is that the movement trajectory of the x-ray generator and the detector is shortened in order to acquire the image of the posterior region.

Figure 11A shows an effective coverage angle for off-axis molar regions outside the center of rotation of the support unit. The coverage angle is maximized when the area of interest is moved closer to the axis of the guide arm 150 and widens when the center of the area of interest is located on the axis of the guide arm 150 as shown in FIG. For reference, FIG. 12 shows an example of grouping partial projection data obtained in various directions by the present invention, in which N sets of projection image sets are obtained in N directions.

The imaging method of the X-ray imaging apparatus according to the present invention can be used in various digital X-ray imaging apparatuses such as panorama imaging apparatus, mammography apparatus and surgeon's cadaver apparatus as described above. And can be used to acquire a three-dimensional structure or sectional image of the object.

On the other hand, the detector 122 may continuously acquire an image of the ROI while moving around the subject. In this continuous acquisition mode, the detector 122 may detect an image of the ROI in the 1 / While recording the projection data, the X-ray generator 121 continuously emits radiation. For reference, in a conventional CdTe detector used in the panoramic imaging apparatus, FR (number of frames per second) is 200.

13A through 14 illustrate a method of processing a group of irregularly projected images when the x-ray imaging apparatus according to the present invention is operated in the continuous acquisition mode. At this time, assuming that each sub-projection image has a view angle of? And that the region of interest is completely covered by N partial projection data that do not overlap with each other, (N-1) x &thetas; and N = 6 in Fig. 13B. The number of partial projected images obtained by the detector 122 is (N-1) x &thetas; / 2 when the stepwise rotation angle of the detector 122 for obtaining the partial projection data is assumed to be beta beta.

Referring to FIG. 13A, each irregular projection image (a set of projection images) when the stepwise rotation angle of the detector 122 is? Can be composed of (N-1) partial projection images, Can be superior in quality, but takes a long time to calculate. Therefore, the partial projection data forming one projection data set for reconstruction can be selected in various forms as shown in FIG. 14, and the start data of partial projection data grouped into one set can be selected in units of &thetas; Thereby grouping into one set of projection images consisting of a minimum number of partial projection data, wherein the different sets of projection images (irregular projection images) differ by a very small angle [beta].

In the present embodiment, the imaging method refers to a method of acquiring projection data and reconstructing an image of a region of interest, for example, a three-dimensional structure or a cross-sectional structure. The present invention relates to a method of reconstructing a tomographic image using a slice as input data for reconstruction Unlike SIS, 3D image of region of interest is obtained by using partial projection data as input data of direct reconstruction algorithm.

More specifically, referring to FIG. 15, a plurality of partial projection data are obtained at a plurality of angles by the X-ray beam emitted from the X-ray generator passing through the region of interest and entering the detector, and the plurality of partial projections The data are grouped so that irregular projection data (a set of projection images) is obtained in each of a plurality of directions. And the irregularly projected data is used as input data for reconstruction to perform image reconstruction for the region of interest. The reconstruction algorithm includes a Block-iterative Reconstruction Technique such as an OSC algorithm (Ordered Subsets Convex Algorithm). More specifically, an image reconstruction technique in CT (Computerized Tomography) can be applied.

As described above, according to the present invention, the present invention can be embodied in other specific forms without departing from the spirit and scope of the present invention. It is obvious to them.

Therefore, the above-described embodiments are to be considered as illustrative rather than restrictive, and the present invention is not limited to the above description, but may be modified within the scope of the appended claims and equivalents thereof.

110: Support unit 121: X-ray generator
122: detector 123: collimator
130: control unit 140: reconstruction unit
150: guide arm 160: frame

Claims (12)

In order to acquire a plurality of partial projection data for a region of interest in which image information is required as a part of a subject, an X-ray generator rotating in a state opposite to the periphery of the region of interest and a detector )step; And
(B) reconstructing an image of the region of interest using the plurality of partial projection data (Sub-projection Data) to obtain image information of the region of interest :
In the step (a), the X-ray generator and the detector are rotated with respect to a rotation center moving on a straight line along one axis, so that the entire region of interest is divided and shot in order to obtain the partial projection data, And acquiring projection data for the entire region of interest. The method according to claim 1,
Wherein the step (b) reconstructs the image of the region of interest using partial projection data that does not have superimposed data among the plurality of projection data and divides the entire region of interest by a fraction. Way. The method according to claim 1,
Wherein the step (a) scans the entire region of interest in a plurality of different directions and acquires a plurality of partial projection data for the ROI in each direction. The method according to claim 1,
Wherein the step (a) comprises: Wherein the plurality of partial projection data obtained by dividing and photographing the entire region of interest in each direction in which projection data for the entire region of interest is obtained through rotation and translational motion of the support unit in which the X- And obtaining an image of the X-ray imaging apparatus. 5. The method of claim 4,
Wherein the step (a) comprises:
Wherein when the angle of the x-ray beam incident on the detector is θ and the support unit moves from the first position to the second position for scanning the entire region of interest in either direction of the region of interest, one time, the center of rotation _{(C 'x, C' y} ) and the position _{(S 'x, S' y} ) of the x-ray generator for the x-ray generator and the detector, respectively (T _x + τv _x, T _y + τv _y) And (S _x + tau v _x , S _y + tau v _y ).
(C _x , C _y ) and the position of the _x- ray generator is (S _x , S _y ) at the first position, and the line connecting the x-ray generator and the detector and the rotation center of the support unit (C _x , C _y ) rotated by θ around (S _x , S _y ) is called (T _x , T _y ); (C _x called, C _y), and focusing on the (M _x, M _y) in the (T _x, T _y), and; (v _x, v _y) is connecting the (M _x, M _y), and (S _x, S _y) the vector; τ represents the moving distance of (T _x, T _y) the vector (v _x, v _y) is moved in a direction (T _x, T _y) for the matching to the line (ℓ)) The method according to claim 1,
Wherein the image of the ROI in the step (b) includes any one of a 3D image and a cross-sectional image of the ROI. The method according to claim 1,
The step (b) comprises: And reconstructing an image of the region of interest by receiving a plurality of partial projection data for the region of interest as input data of the reconstruction algorithm. A support unit capable of translational motion and rotational motion and rotating based on a rotation center moving along a straight line along one axis;
An image capturing unit having an X-ray generator provided at one side of the support unit for emitting X-rays and a detector provided at the other side of the support unit so as to move in a state facing the X-ray generator;
Wherein the X-ray generator and the detector move in a state in which the X-ray generator and the detector are opposed to each other to capture a plurality of partial projection data for the region of interest, A control unit for controlling the movement of the support unit to scan the whole; And
And a reconstruction unit for reconstructing an image of the region of interest using a plurality of partial projection data for the region of interest, the apparatus comprising:
Wherein the image capturing unit photographs the entire region of interest to obtain the partial projection data and obtains projection data for the entire region of interest in a plurality of different directions. 9. The method of claim 8,
The control unit comprising: Wherein the angle of the x-ray beam incident on the detector is &thetas; and the support unit moves from the first position to the second position for scanning the entire region of interest in either direction of the region of interest, (C _x , C _y ) of the x-ray generator and detector and the positions (S _x , S _{y y} ) of the x-ray generator are (T _x + τv _x , T _y + τv _y ) (S _x +? V _x , S _y +? V _y ).
(C _x , C _y ) and the position of the _x- ray generator is (S _x , S _y ) at the first position, the line (k) connecting the x- (T _x , T _y ), which is rotated about θ by (C _x , C _y ) about (S _x , S _y ), is an angle formed by a line (l) ; (C _x, C _y) and as the midpoint of _{(T x, T y) (} M x, M y) , and; (v _x, v _y) are (M _x, M _y), and (S _x, S _y) the connecting vector is; τ is (T _x, T _y) the vector (v _x, v _y) is moved in a direction indicating a moving distance of (T _x, T _y) for the matching to the line (ℓ) ) delete 9. The method of claim 8,
Wherein the reconstruction unit reconstructs an image of the region of interest using partial projection data that does not have overlapping data among the plurality of projection data and divides the entire region of interest by a fraction. The method according to any one of claims 8, 9 and 11,
Wherein the x-ray imaging apparatus is a panorama imaging apparatus.

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