KR840001728B1 - X-ray television system - Google Patents

Abstract

An X-ray image from an image intensifier is projected on an image pickup surface of a television vamera. The television camera converts the X-ray image into a video signal. The video signal is reproduced as an X-ray image on a monitor television. In ordinary fluoroscopic photographing, the video signal is blanked and supplied to the monitor television. In cine-photographing, on the other hand, the X-ray image, constricted by an X-ray stop, is projected on the televisdsion camera, a scanning region substantially identical with the constricited X-ray image is supplied to the monitor television without being blanked.

Description

X-ray TV device

1A and 1B are explanatory diagrams of a scanning and display state during perspective photography in a conventional apparatus.

2A and 2B are explanatory diagrams of scanning and display states during cinematography in a conventional apparatus.

3 is a block diagram of one embodiment of the present invention.

4 is a circuit diagram of an example of a control circuit used in the embodiment of FIG.

5A and 5B are explanatory diagrams of a scanning and display state in perspective photographing by the apparatus of the present invention.

6A and 6B are explanatory diagrams of a scanning and display state during cinematography by the apparatus of the present invention.

7 is a block diagram of a blanking processing circuit.

8a, b and c are explanatory views of the blanking operation.

The present invention relates to an X-ray TV apparatus of a system of monitoring by using a television (hereinafter referred to as a TV) at the time of X-ray diagnosis.

A conventional X-ray TV apparatus receives a ray transmitted from an object under an image intensitier (hereinafter referred to as II), converts it into a fluorescent image, and outputs the output image to a camera through an optical system. The video signal is sent to a TV monitor to display an X-ray perspective image on the TV monitor. When the output image of II is imaged on the image pickup tube of the TV camera through the optical system, the output image of II is circular, so as shown in FIG. 1A, the output image of II is displayed inside the circular photoconductive surface 1 of the image pickup tube. (2) is included and an image is formed, and a TV camera is scanned to display a substantially rectangular scanning surface 3 circumscribed to the formed circular shape 2. Therefore, when displayed on a TV monitor, a scanning area other than the output image of II has no information amount, so that a mask which does not transmit light to the monitor display surface in accordance with the diameter of the output image 2 of II is attached or Circle blanking was done on the TV camera. That is, for example, as shown in FIG. 1B, a mask 5 having a circular window 5a corresponding to the diameter of the output phase II on the CRT (Cadodue Ray Tube) 4 of the TV monitor in the center. (The shaded part in the drawing) was attached so that the raster was a square scanning surface 6 circumscribed to or slightly larger than the circular window 5a. However, in diagnosing circulatory system, when a cinematography (short time continuous imaging) is performed after a catheter is inserted into a target site (for example, in the heart), the X-ray tube can be removed to remove scattered lines around the image. The X-ray tightening on the front side is tightened like the rectangle 13 in FIG. 2a. For this reason, the image displayed on the monitor becomes a rectangular image 13 'inscribed in the circular screen 15 as shown in FIG. 2B.

As is evident from the above description, there is a drawback that the area for displaying the effective image is smaller than the displayable area of the CRT 4 in both normal perspective shooting and cinema shooting. That is, the shaded portion 5 of FIG. 1b and the shaded portion 16 of FIG. 2b become obsolete, so that the image displayed on the CTR 4 is small, so that the resolution is degraded, and the problem is caused. .

It is therefore an object of the present invention to provide an X-ray TV apparatus capable of improving the large screen and resolution capability of display images by increasing the area of the effective image occupying the CTR.

Hereinafter, the present invention will be described in detail with reference to Examples.

3 is a block diagram showing an example of a schematic configuration of the X-ray TV apparatus of the present invention. The apparatus includes an X-ray tube XT and an image enhancer tube II disposed to face each other with the subject P interposed therebetween, an X-ray tightening XC provided between the X-ray tube XT and the subject P, and an optical system OP disposed at the output side of the II. And a TV camera TC installed at the output tip of the optical system OP, a TV camera controller CC for controlling the TV camera, a TV monitor MT, a control unit CB for controlling the TV monitor MT and the TV camera controller CC, and this control unit It is composed of foot switch F. SW for switching operation of CB. Incidentally, the specific configuration of the control unit CB, which is a characteristic part of the apparatus, is as shown in FIG. That is, it consists of three relays RL ₁ -RL ₃ and the circle blanking circuit 11. A pair of contact terminals of relays RL ₁ and RL ₂ are connected to the camera head TC and the camera controller CC respectively, and a pair of upper joints (indicated by white circles in the figure) have resistors R ₁ , R ₃ , The resistors R ₂ and R ₄ are connected to a pair of contacts (indicated by black circles in the drawing), and the contact terminals of the other relays RL ₃ are connected to the TV monitor MT. It is connected to the output side of the click blanking circuit 11, and the bottom contact (shown with a white circle in the figure) is connected to the input side of the circle blanking circuit 11. In addition, these three relays RL _1- RL ₃ are controlled by the foot switch F. SW provided below. That is, normally, the relays RL _1- RL ₃ are closed to one contact point (black circle in the figure), but are controlled to close to the other contact point (white circle in the figure) as the foot switch F.SW is closed. . In addition, the input point of the circle blanking circuit 11 is connected to the output terminal of the camera controller CC. In addition, the resistors R ₁ -R ₄ connected to the relays RL ₁ and RL ₂ are for setting the scan size of the scan line in the TV camera TC, R1 and R2 are for the horizontal scan line, and R ₃ and R ₄ are for the vertical scan line. to be. Therefore, by changing the values of the resistors R ₁ and R _{3 provided} on the upper side and the resistors R ₂ and R ₄ provided on the lower side, the scanning size before and after the relay operation is changed by changing the scan size before and after the relay operation. You can change it. That is, the value of each resistor is set to change the amplitude of the horizontal and vertical sawtooth waves. In this embodiment, the resistors R ₂ and R ₄ include an output phase 2 with a scanning range for the II output phase 2 formed on the photoconductive surface 1 of the imaging tube as shown in FIG. The values are selected so as to have a size representing the rectangular area 9 having an aspect ratio of approximately 3: 4 (that is, a size having a similar shape to the CRT 4), and the resistors R ₁ and R ₃ are shown in FIG. As shown in the figure, the upper, lower, left, and right portions 14 of the II output image 2 are set to the same value as scanning the same range as the rectangle 13 in the state of being tightened by X-ray tightening XC. In other words, when the relays RL ₁ and RL ₂ in the control unit CB do not operate, the scan size becomes as wide as possible, and conversely, when the relay operates, the scan size becomes narrow. In addition, the circle blanking circuit 11 in the control unit CB has a function of displaying the periphery of the II output phase 2 in FIG. 5A in a blanking state, that is, when the relay RL ₃ does not operate. When the contact piece terminal of relay RL ₃ is connected to the contact marked black, the above function is performed. When the relay RL ₃ is operated, that is, the contact point where the contact piece terminal of relay RL ₃ is displayed in white is connected, the function is released. It is supposed to be. The circle blanking circuit 11 is a well-known circuit, the configuration of which is shown in a block diagram in FIG. 7, and its operation is shown in FIG. Referring to FIG. 8B, which shows an enlarged portion of the time T ₁ of the waveform (f, g) in the waveform of (a), and FIG. 8C showing a blanking process in the TV monitor by such a waveform.

As shown in the above block diagram, the vertical synchronizing signal and the horizontal synchronizing signal used for normal TV image scanning are input to the monostable multivibrator, respectively. The vertical synchronizing signal and the horizontal synchronizing signal are divided by appropriate CR time constants in the monostable multivibrator, and a square wave like waveform (b) is generated. This square wave is integrated in the first integrating circuit to generate a sawtooth wave such as waveform (c). It is then integrated in a second integrating circuit with a feed back circuit to generate a parabolic wave as shown by waveform d. Next, the parabolic waves on the vertical synchronous signal side and the horizontal synchronous signal side are added by the addition circuit so that the horizontal synchronous signal side parabola waves are added by the voltage level of the vertical synchronous signal side parabola waves to form a waveform as shown by the waveform (e). The threshold value is then set to the parabolic wave on the horizontal synchronous signal side as shown by the waveform f by generating the voltage V of the predetermined level as the threshold circuit. The pulsed circuit generates a square pulse having a width corresponding to the level of the parabolic wave having a level lower than the threshold V (waveform g).

By irradiating the TV monitor with the spherical pulse g, a blanking process is performed according to the width of the spherical pulse, whereby a circular video range is obtained in the TV monitor.

Also, above the optical system OP of FIG. 3, the cinema camera CINE. C is arranged.

In such a device, the X-rays from the X-ray tube XT are limited by the X-ray tightening XC to penetrate the subject V, and are input to the input fluorescent surface 7 of I.I. In the input fluorescent surface of I.I, the see-through image is converted into a fluorescent image and drawn to the output fluorescent surface 8 in an appropriately amplified form. The fluorescent X-ray image is captured by the TV camera TC through the optical system OP, and the video signal is sent to the TV monitor MT through the camera controller CC and the control unit CB for display. Here, in general perspective shooting, the foot switch F.SW is not used, but in the case of cinema shooting.

These two photographing modes will be described in turn with reference to FIGS. 5 and 6. First, during normal perspective photography, scanning and display as shown in Figs. 5A and 5B are performed. That is, as shown in FIG. 5A, the scanning line of the TV camera TC scans the rectangle and the scanning area 9 on the aspect ratio of approximately 3: 4 with respect to the II output image 2 formed on the photoconductive surface 1 of the imaging tube. In this case, as shown in FIG. 5B, the TV monitor beam-scans the scanning area 10 (surrounding the CRT 4) having an aspect ratio of approximately 3: 4 on the CRT 4. In the circle blanking circuit 11, the portion 17 ′ corresponding to the periphery 17 of the II phase 2 is blanked in advance to display the circular image 12. However, at the time of cinema shooting, scanning and display as shown in Figs. 6A and 6B are made. That is, the portion corresponding to the upper, lower, left, and right peripheral portions 14 of the II output image 2 shown in FIG. 6A by P-line tightening XC is tightened to prevent deterioration of image quality by scattering lines, and is inscribed. The rectangular area portion 13 becomes an effective image range. At this time, the control unit CB switches the relays RL _1- RL ₃ by pressing the foot switch F. SW, releases the circle blanking circuit 11, and sends the output of the TV camera controller CC to the TV monitor MT as it is. At the same time, the scanning size setting connected to the TV camera TC and the camera controller CC causes the resistances R ₁ and R ₃ to be scanned so that the resistors R ₂ and R ₄ are approximately matched with the effective image portion 13. In the TV monitor MT, as shown in FIG. 6B, the image is displayed on the displayable portion of the CRT 4 in full. In this way, since the display becomes a large screen, the displayable portion of the CRT can be effectively used, and since the resolution is improved, the degree of diagnosis can be improved. In addition, since the image displayed on the CRT is approximately identical to the image recorded on the cinematographic film, the part necessary for diagnosis is not prevented from being recorded.

The present invention is not limited to the above embodiment, for example, when the foot switch F. SW is pressed, the secondary lens of the optical system OP is mechanically focused instead of changing the scanning range of the scanning line of the camera TC and the camera controller CC. The same object may be achieved by switching the distance to a larger one. In addition, it is possible to achieve more accuracy by interlocking with the tightening operation of the P-line tightening XC so as to change the scan size setting resistors R ₁ and R ₃ in the horizontal and vertical directions. In addition, it is more convenient to simultaneously switch between the P-line tightening XC and the scan area switching relays RL ₁ , RL ₂ and relay RL ₃ with the foot switch F.SW. In addition, the scan size setting resistors R _1- R ₄ may be incorporated in the TV camera TC and the camera controller CC, and the relay RL _1- RL ₃ switching switch may be used without being limited to the foot switch. The switching means may use electronic means, not just relays.

According to the present invention described above, since the area of the effective image occupied on the CRT can be increased, the large screen and the resolution of the display image can be improved.

Claims (1)

An X-ray generator for irradiating X-rays to the subject, an X-ray tightening for varying the X-ray irradiation region in the X-ray generator, an image intensifier tube for converting X-rays transmitted through the subject into fluorescent images, An X-ray TV apparatus comprising a TV camera apparatus for converting a fluorescent image of an image enhancement tube into a video signal, and a TV monitor for displaying a video signal from the TV camera apparatus. And an image display control device for selectively outputting a scanning electron beam deflection control signal on the light conducting surface of the device, and selectively outputting a circle blanking signal to an electric TV monitor. The image display control device is connected to a TV camera device. A deflection amount setter for switching and setting the electric scanning electron beam deflection amount into various kinds; a circle blanking signal generator for generating a circle blanking signal; and a circle blanking signal generator And a switching device including a blanking switching connector set between the vitality and the TV monitor, and outputting a control signal for interlocking control of the electric deflection amount setting device and the blanking disease connector.

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