KR100353591B1 - Apparatus for high resolution digital radiography using multiple imaging devices - Google Patents

Abstract

The radiographic apparatus of the present invention is a device for taking a high-resolution X-ray image in real time, overcoming the problems of the conventional imaging apparatus that takes a long time and additional efforts to digitize data because the use of a film, a predetermined wavelength Light generating means for generating a light of the light source, the light generated by the light generating means transmitted through the subject to the visible image to obtain a visible image and a plurality of image pickup elements, the visible image by the visible image acquisition means is divided and enlarged And a digital detector for converting each divided image into an electrical signal and outputting the digital signal, a digital signal processor for processing and outputting the electrical signal output from the optical detector, and a digital signal output from the digital signal processor. Consists of a display unit and a control unit for controlling the operation of the photographing apparatus as a whole When X-rays are irradiated to the human body in the chain, X-rays passing through the human body are converted into visible light, and these gas rays are converted into electrical signals to display the structure of the human body on a monitor or to store the structure of the human body in data and store it in a storage medium. The present invention relates to a radiographic apparatus.

Description

Apparatus for high resolution digital radiography using multiple imaging devices

The present invention relates to a photographing apparatus for converting, processing, and displaying information of a subject photographed using radiation in real time into digital data, and more particularly, X-rays penetrating the human body when the human body is irradiated with radiation. Is converted into visible light, converted into visible light again into an electrical signal, and converted into digital data to display the structure of the human body on a monitor, and the structure of the human body is digitalized and stored on a storage medium for immediate display. It relates to a photographing apparatus.

Diagnostic radiation devices widely used in general hospitals are classified into an X-ray generator that emits X-rays and a film that develops a film and a film that appear in proportion to the intensity of X-rays emitted from the X-ray generator and penetrating the human body. In order to photograph a specific part of the human body using such a diagnostic radiographer, the photographer mounts a film disc, drives an X-ray generator, and determines what changes are made in a specific location of the human body by developing the film.

However, the process of attaching a new film disc and developing it every time the human body is taken is time consuming and cannot be taken continuously, and it takes a lot of effort and expense to keep the film taken and to find the desired film from the stored film if necessary. In addition, in the era of medical informatization, in which all medical images are digitized, an additional cost is incurred in converting a radiographic image using an analog-printed film into digital data. A lot of research and development on the real-time digital imaging apparatus to replace. Most of the systems under development so far have a structure of adsorption of phosphor or amorphous silicon on TFT liquid crystal, which has high resolution and high light conversion efficiency, but has low manufacturing yield and high cost. Another method is to use an optical conversion device that converts X-rays into visible light, an optical system, and a charge coupling device (CCD or CMOS imager). This has the advantage of being cheaper than the method described above. However, there is a problem that the resolution is low for use in medical purposes for the purpose of diagnosis of the disease. In case of general purpose charge coupling device, it is about 600 particles (360,000 total particles) each in width and length, and in case of scientific charge coupling device, resolution of less than 1024 particles (about 1 million particles) in each direction Has Therefore, when a high resolution image such as a medical diagnostic device requiring at least 2000 particles in width and length is required, a single charge coupling device cannot satisfy the required specification. An object of the present invention is to provide an inexpensive and high resolution radiographic imaging apparatus using a plurality of charge coupling elements (imaging elements).

1 is a block diagram showing a radiographic apparatus according to the present invention,

2A-2C are diagrams for explaining the principle of a photographing apparatus according to the present invention using a plurality of imaging elements;

3 is a view for explaining the optical system fixture of the present invention,

4 is a diagram showing the configuration of a digital signal processing unit of the present invention;

5 is a view for explaining a method for receiving image data from six image pickup circuits by the image information collecting circuit according to the present invention;

* Explanation of symbols for main parts of the drawings

10: X-ray generator 11: X-ray

12: visible light 13: data signal line

14, 15: horizontal signal line 16 ~ 18: vertical signal line

20: Subject 30: X-ray / visible light conversion unit

31: Partial Visible Image 32: Overlapped Visible Image

40: optical system 41: optical element

42: optical fixture 50: charge coupling portion

51: image pickup device 52: light detection sensor

60: digital signal processor 61: image information acquisition circuit

62: image information correction circuit 63: PCI drive circuit

70: display unit 80: data storage unit

90: control unit

Radiation imaging apparatus of the present invention for achieving the above object is a light generating means for generating light of a predetermined wavelength, visible image acquisition means for converting the light transmitted from the light generating means transmitted to the subject into a visible image, a plurality of And a light detecting means for dividing the visible image by the visible image acquiring means and converting each of the divided images into an electric signal, and outputting the digital signal by processing the electric signal output from the light detecting means. A digital signal processing unit for outputting, a display unit for displaying a digital signal output from the digital signal processing unit, and a control unit for controlling the operation of the photographing apparatus as a whole. Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Fig. 1 shows a block diagram of a radiographic apparatus according to the present invention. As described above, the X-ray generator 10 is a light generator that emits light of X-ray wavelength. Although the embodiment uses X-rays, it is also possible to use an embodiment in which light having a different wavelength that can penetrate the object 20. The X-ray / visible ray conversion unit 30 is X as a means for obtaining a visible image. For forming a visible image that converts the X-ray 11 transmitted from the line generator 10 and transmitted through the subject 20 into visible light 12, a cesium iodide (CsI) thin film, and gadolinium oxy sulfide (Gd _2). O ₂ S: T _b ) or yttrium oxy sulfide (Y ₂ O ₂ S: T _b ). The optical system 40 is composed of a plurality of optical elements 41, such as a camera lens, for X-ray / visible light conversion. The visible light 12 emitted from the unit 30 is collected and transferred to the charge coupling unit described later. The charge coupling unit 50 includes a plurality of charge coupling elements (hereinafter, referred to as "imaging elements") 51. Dividing the visible image formed by the line / visible ray conversion unit 30 and shooting each divided image. And outputs the converted to red light. At this time, each imaging device 51 is provided to correspond one-to-one with the optical device 41. That is, the image signal changed into the visible light 12 by the X-ray / visible light conversion unit 30 is a plurality of imaging elements 51 corresponding to each optical element 41 one-to-one through a plurality of optical elements 41 Each image pickup device 51 converts each of the divided image signals into electrical signals and outputs the converted electrical signals. As such, the charge coupling unit 50 of the present invention having a plurality of imaging devices 51 can acquire an image with a higher resolution than the conventional imaging device composed of one lens and one imaging device. For example, when a visible image formed on the X-ray / visible ray converting unit 30 having a size of 400 mm horizontally and vertically is photographed using only one imaging device composed of 400 pixels each horizontally and vertically, particle 1 of the digital image The size of the dog will be 1 mm in width and height respectively. Increasing the number of particles of the imaging device increases the resolution of the digital image, but there is a limit to increasing the number of particles of the imaging device. Therefore, the present invention uses a method of having a high resolution by using a plurality of conventional imaging devices having a limited number of particles, which will be described later in detail. The digital signal processing unit 60 is converted by the charge coupling unit 50. Converts the converted electrical signal into a digital signal and outputs it to the display unit 70 and / or the data storage unit 80, and the whole of the photographing apparatus such as the digital signal processing unit 60, the display unit 70 and the data storage unit 80. The operation is precisely controlled by the controller 90. FIGS. 2A-2C are diagrams for explaining the principle of the photographing apparatus according to the present invention using a plurality of imaging elements, and FIG. 2A is a plurality of optical elements 41. FIG. And it is a view for explaining the principle of photographing by dividing the visible image by the X-ray / visible light conversion unit 30 by using the image pickup device (51). Referring to FIG. 2A, each imaging device 51 has an optical element 41 corresponding to one-to-one, and has a structure capable of capturing each partial image 31 by dividing the entire visible image into a predetermined size. At this time, the partial image 31 photographed by each image pickup device 51 has a portion 32 slightly overlapped with a portion captured by neighboring image pickup devices 51, which is each image pickup device 51. Images may not be photographed at the boundary portion, and a portion of the visible image of the X-ray / visible ray conversion unit 30 may not be captured by an error generated when assembling the plurality of imaging devices 51. Each optical element 41 is fastened and fastened by a fixture described later with a certain distance (focusing distance) from each image pickup element 51, and mounted with a photodetector sensor 52 on the charge coupling unit 50 The brightness value of the visible image generated by the X-ray / visible ray conversion unit 30 may be measured. In order for the image pickup device to obtain an optimal image, the X-ray / visible ray conversion unit 30 should have an appropriate illuminance, which can be measured using the light detection line 52. The amount of light measured by the light detection sensor 52 is input to the controller 90 through a measurement circuit not shown, and the controller 90 calculates an optimal exposure time for the image pickup device 51 to obtain an optimal image. Transfer to an image pickup device controller (not shown). In fact, when obtaining a radiographic image, an image pickup device controller (not shown) accumulates an image signal for a predetermined exposure time and transmits the image information to the digital signal processor 60. FIG. 2B illustrates an embodiment using the present invention. The visible image of the X-ray / visible ray conversion unit 30 is photographed using nine imaging devices. Of these, only a portion of the "ga" shape is picked up by the image pickup device on the upper left side. FIG. 2C shows that at least any portion of the X-ray / visible ray conversion unit 30 is extended by widening the shooting range of each optical element 51. An embodiment configured to allow photographing by two imaging devices is shown. The imaging device 51 instantaneously generates an amount of charge that a particular particle cannot handle and overflows with the surrounding particles, causing bright and small dots to appear on the screen (Blooming phenomenon). X-ray imaging can cause a big error in diagnosis. Therefore, if any part of the X-ray / visible ray conversion unit 30 can be photographed by at least two imaging devices as shown in FIG. 2C, this phenomenon can be coped with. For example, when the same part 32 of the X-ray / visible ray converting unit 30 appears to have different brightnesses in two different imaging devices, the controller 90 may cause such a difference in brightness to bloom. In this case, the digital signal processing unit 60 uses only signals from the normal image pickup device among the signals from the two image pickup devices in the case of the blooming phenomenon. FIG. 3 is a view for explaining an optical system fixture. The fastener 42 has a structure in which the optical element 41 is mounted on one side and the image pickup element 51 can be mounted on the other side at a predetermined distance (focus distance). One embodiment and a cross-sectional view showing an image pickup device 41 and an optical device 41 are shown. The optical fixture 42 has a shape in which one corner protrudes convexly, and two adjacent corners thereof are concave to engage with the above-described protrusion. 3B shows a state in which a plurality of optical system fixing groups 42 are connected, but six fasteners 42 are connected, but it can be seen that the number of fasteners 42 can be easily expanded or reduced. In this manner, the assembly of the present invention is very easy when the plurality of imaging elements 51 are to be used by the use of the fastener 42. Fig. 4 is a diagram showing the configuration of the digital signal processing unit 60. The signal processing unit 60 excludes overlapping portions of the plurality of pieces of images collected by the image information collecting circuit 61 and the image information collecting circuit 61, which collect electrical signals output from each image pickup device 51. High-speed information for quickly transmitting the digital image output from the image information correction circuit 62 and the image information correction circuit 62 which combines only the necessary parts to form a single high precision image and corrects the distortion of the image generated by the characteristics of the optical system. And a Peripheral Component Interconnect (PCI) driver circuit 63 as a transmission means. The image information output from the digital signal processor 60 controls the display unit 70 under the control of the controller 90. Or is stored and stored in the data storage unit 80. In addition, such information may be easily shared with other systems through a data transmission system such as a picture archiving and communication system (PACS). FIG. 5 shows that the image information collection circuit 61 captures six images. It is a view for explaining a method of receiving data from the elements 51. An image pickup device controller (not shown) is attached to the rear surface of each image pickup device 51, and each of the image pickup device controllers (not shown) and image information are shown. The data signal line 13 is connected between the collection circuits 61. The data signal line 13 has a matrix structure divided into horizontal signal lines 14 and 15 for transmitting data in the horizontal direction and vertical signal lines 16, 17 and 18 for transmitting data in the vertical direction. 14 to 18 are composed of a data signal line for transmitting a video signal, a selection signal line for selecting the image pickup device 51, and a control signal line for controlling the function of the image pickup device 51. In other words, each image pickup device controller (not shown) is connected to the image information collection circuit 61 by horizontal signal lines and vertical signal lines to communicate with each other. The method of receiving image information from the method is as follows. First, the image information collection circuit 61 sends a selection signal to the horizontal signal line and the vertical signal line corresponding to the image pickup device to which the image information is to be obtained. Each imaging device controller (not shown) outputs image information only when a selection signal is applied to both the horizontal signal line and the vertical signal line. When the data lines are formed in this way, the wiring is simplified because the image pickup devices 51 are not connected in one-to-one correspondence. For example, as shown in FIG. 5, the number of wirings between the charge coupling unit 50 and the image information collecting circuit 61 is only 5 data signal lines 13 in both the two horizontal signal lines and the three vertical signal lines. All you need is This configuration has a large number of image pickup devices, and more effectively, in a case where a total of 36 image pickup devices are arranged in a total of six horizontally and vertically, 36 data signal lines are connected when each image pickup device 51 is connected to the image information collection circuit 61, respectively. Although necessary, in the present invention, only 12 signal lines 13 are required.

As described above, X-rays transmitted through a subject are converted into visible light in real time, and the converted visible light is converted into an electric signal and displayed on a monitor or stored on a recording medium, etc., and displayed whenever necessary, which is useful for hospitals and the like. It can be, and can eliminate all the defects that occur when using the film in the conventional X-ray imager. In particular, by using a large number of lenses and imaging devices, it is possible to secure a high resolution at a low cost, thereby providing easy access to medical applications or high precision measurement fields in aerospace, where high resolution is essential.

Claims (12)

In the video recording apparatus, Light generating means for generating light of a predetermined wavelength; Visible image acquisition means for converting the light generated by the light generation means and transmitted through the subject into a visible image; A light detecting means having a plurality of image pickup devices for dividing and capturing a visible image by the visible image obtaining means, and converting each of the divided images to be output as an electrical signal; A digital signal processing unit for processing and outputting an electrical signal output from the light detecting means as a digital signal; A display unit which displays a digital signal output from the digital signal processing unit; And And a controller for controlling the operation of the photographing apparatus as a whole. The radiographic apparatus according to claim 1, wherein the light generating means is an X-ray generator for generating light having an X-ray wavelength. The method of claim 1, wherein the visible image acquisition means is any one of cesium iodide (CsI) thin film, gadolinium oxy sulfide (Gd ₂ O ₂ S: T _b ), yttrium oxy sulfide (Y ₂ O ₂ S: T _b ) Radiography apparatus, characterized in that. The method according to any one of claims 1 to 3, wherein the light detecting means A plurality of optical elements for dividing and photographing the visible image from the visible image obtaining means; And a plurality of imaging devices provided in one-to-one correspondence with each optical device and converting a visible image photographed by the optical device into an electrical signal. delete 5. The radiographic apparatus according to claim 4, wherein each optical element divides and captures a visible image from the visible image obtaining means so that the visible image portion and the boundary portion captured by other adjacent optical elements overlap each other. . The radiographic apparatus according to claim 4, wherein the optical device photographs the visible image from the visible image acquisition unit such that at least two different optical devices overlap each other. delete 5. The radiographic apparatus according to claim 4, wherein the light detecting means further comprises a light detecting sensor for measuring the brightness of the visible image from the visible image obtaining means to determine an optimal exposure time of the image pickup device. . 5. The radiographic apparatus according to claim 4, wherein the light detecting means further comprises a plurality of fasteners for fixing the optical bath and the image pickup device corresponding to each optical element. The method of claim 4, wherein the digital signal processing unit An image information collecting unit collecting a plurality of pieces of visible images converted into electrical signals in each image pickup device; Image information report for reconstructing the original visible image and correcting the distortion of the image by collecting only the non-overlapping portions except for the overlapped portion of the pieces of the visible image collected in the image information collecting unit government; And information transmitting means for quickly transmitting the digital image formed by the image information correcting unit. 12. The method of claim 11, wherein the light detecting means and the image information collecting unit are connected by at least one horizontal signal line and at least one vertical signal line, wherein the horizontal signal line and the vertical signal line are connected to each other in a matrix form. And each of the image pickup devices is connected to the image information collecting unit through a horizontal signal line and a vertical signal line.