CH630176A5 - Method of producing a tomogram and device for tomographically investigating an object - Google Patents

Description

The invention is explained in more detail below with reference to the drawing. Show it:

-Fig. 1 schematically shows an embodiment of a device according to the invention;

FIG. 2 shows a part of the device according to FIG. 1 with an x-ray source with line focus;

3 shows an embodiment of a mirror-optical system with which the detector surface is imaged on the photocathode of an image intensifier tube;

4 shows an embodiment of a fiber optic system with which the detector surface is imaged on the photocathode of a brightness intensifier tube;

5 shows an embodiment in which the detector surface is arranged directly inside the piston of an X-ray image intensifier tube; and

6 shows an embodiment of a detector surface designed as a cylindrical surface, for use in an X-ray source with a line-shaped focus; and

—Fig. 7 shows the use of a detector surface according to FIG. 6 in a device of the type shown in FIG. 1.

The device shown in FIG. 1 comprises an X-ray source 1 and an X-ray screen 2. When the device is in operation, an object 3 becomes between these two parts

attached, wherein in this figure the case is taken that the center of this object lies on the perpendicular from the source 1 on the screen 2. In operation, when the object is attached in this way, essentially half of the cross section of this object is irradiated by the radiation from the source 1 and a transmission image of a disk-shaped cross section of the object is generated on the screen 2 when the object rotates through 360 ° .

On the side of this screen 2 io facing away from the source 1 there is also a very bright optical system 4, which is intended to image the image on the X-ray screen 2 on the photocathode of an image intensifier 5.

In the embodiment according to the invention depicted in FIG. 1, this image intensifier 5 is coupled directly with fiber optics 15 to a television recording tube 6 located behind it. This television recording tube is used to scan the image appearing when the device is operating on the anode screen of the image intensifier 5 in the manner customary in television technology, this tube 6 then providing a video signal, which is fed to a monitor 9 and a logarithmic video amplifier 7 , which in turn, as is evident from the figure, is coupled to an image reconstruction device 8. The image reconstruction device 8 then uses the received video signals to form a tomogram of the object cross section in question.

It is clear that the object 3 must be rotated about an axis during operation or that the set, consisting of the x-ray source 1 and the screen 2, must be rotated about the object 3; this is indicated schematically in the drawing 30 by an arrow.

As can be seen from the figure, the use of a relatively small detector area is sufficient here to obtain all the information necessary for the final reconstruction of a complete cross-sectional image, while avoiding any translational movement. Due to the fact that in the arrangement of the object 3 shown in the figure only part of the cross-section of the object 3 is always shown on this screen 2, in order to obtain a complete cross-sectional image of the object 3, the latter must have an angle 40 of 360 ° around the axis of the Object can be rotated. The disadvantage of complete rotation is less than the advantages obtained by a small-area detector surface, especially if the device is arranged so that the axis of rotation is vertical.

45 The use of a relatively small detector area further enables the other components of the system, such as the optical system 4, the image intensifier tube 5, etc., to have smaller dimensions and consequently to be cheaper. In addition, these smaller dimensions lead to lighter designs with less moment of inertia, which means that much faster rotation can be achieved with much lower power. This can drastically limit the influence of motion blur as a result of movements of the object.

It is a further advantage of the relatively small detector area 2 that a good resolution is obtained with the device, because a television picture, the resolution of which is determined by the number of television lines and the bandwidth used, for processing the information, each of about 60 half of the object 3 originates, is used, and consequently in the reconstruction of the entire object 3 makes a proportionally smaller contribution to the blur and at the same time, for example, a doubling of the resolution occurs in the horizontal sense than in the case and in the event that the detection 65 door area has a larger dimension and a television picture is used for the whole object.

Furthermore, it is clear that although in the drawing the case is indicated that the axis of rotation of the object 3 on the sink

630176

4th

on the right from the X-ray source 1 on the screen 2, this is not absolutely necessary so that the axis mentioned cannot lie directly on, but also close to, one of the side edges of the fan-shaped beam within it. 5

Arranging the object 3 as indicated in Fig. 1 has both a disadvantage and an advantage. The disadvantage is that a so-called “central core” is created on the edge of the screen at the bottom of the figure, which appears as a dot in the tomogram. However, it is possible to use this io "central core" as a reference, e.g. is important for the targeted irradiation of individual object areas. It turns out that this advantage outweighs the visual disadvantage of creating the point in the reconstructed image,

also considering the freedom to choose this "central core" in a less important part of the cross-section.

The x-ray source preferably has a line-shaped focus, directed parallel to the axis of rotation of the object or set, consisting of the x-ray source and the screen, as shown in FIG. 2 of the drawing. In this case, it is also possible to give the detector surface, if it lies outside the piston of an image intensifier, the shape of part of the jacket of a cylinder, the axis of which corresponds to the line-like focus of the X-ray source, as indicated in FIG. 6, 25 thereby avoiding it that along the detector surface would have to be corrected for a linear magnification.

7 shows an application of such a concavely curved detector surface in a device of the type shown in FIG. 1. The device again comprises an X-ray gene source 1 and an X-ray screen 2, which in this case is concave. An object 3 is arranged between these two parts in the manner mentioned above.

On the side of the screen 2 facing away from the source 1 there is an optical system, shown here as a lens 4, in order to image the image on the screen 2 on the photocathode 14 of an image intensifier 5.

In connection with the concave shape of the screen 2, the incidence surface of the image intensifier is also concave in this embodiment. A fiber optic 13 is then located between this incident surface and the photocathode 14 of the image intensifier 5, as is also found in the embodiment according to FIG. 4.

Where there is talk of a screen or a detector surface above, we mean a construction that can be composed of a two-dimensional matrix of discrete X-ray detector elements or a continuous, two-dimensional X-ray screen.

It is further pointed out that although in the embodiment shown in FIG. 1 the image on the detector surface is imaged on the photocathode of the brightness intensifier tube 5 by means of a lens system 4, this can also be done with the aid of a mirror system, as indicated in FIG. 3. In this embodiment, a beam emanating from the detector screen 2 is directed via a curved lens 10 against a mirror 11 provided with a central opening, which reflects the beam back to a curved mirror system 12, which in turn throws the beam onto the photocathode of the image intensifier 5. As shown in FIG. 4, the imaging can also take place using fiber optic means. In this case, fiber optics 13 are pre-shirts between the detector screen 2 and the photocathode of the image intensifier 5.

Furthermore, in the embodiment shown in FIG. 1, the detector surface 2 is specified outside the envelope of the image intensifier tube 5; however, it is also possible for the detector surface to be located within the envelope of a direct X-ray image intensifier tube, as indicated in FIG. 5. As can be seen from this figure, the detector screen 2 is located in the immediate vicinity of the photocathode 14 of the image intensifier 5 within its envelope. It is precisely the small extent of the detector area according to the invention that makes it possible to implement such a construction.

As already noted above, during operation of the device it is possible to rotate the object 3 with respect to a stationary system of X-ray source 1 and screen 2, and to rotate the latter system with respect to a stationary object 3.

Finally, the device can be provided with means by which the position of the disk-shaped object cross section can be adjusted relative to the set consisting of the X-ray source 1 and the detector surface 2. These means are also not expressly reproduced in the embodiments shown schematically in the drawing.

C.

1 sheet of drawings

Claims (12)

63 (1176 PATENT CLAIMS 1. A method for producing a tomogram, in which the object to be examined is arranged between an x-ray radiation source and a detector surface, a layer of the object is projected from this radiation source onto the detector surface, while the object and x-ray source with the detector surface are relative to one another X-ray beam emitted by the X-ray source, the vertical axis are rotated, the images appearing successively on the detector surface are converted into signals which correspond to the X-ray absorption image of the layer in different directions, and these signals are processed to form a tomogram of the layer, characterized in that the rotation takes place about an axis of rotation which intersects the fan-shaped x-ray beam at a point which is at least approximately at one of the two diverging side edges of the fan-shaped x-ray beam, so that essentially only that part of the layer is projected which is located on one side of the axis of rotation, the thickness of the layer in the direction of the axis of rotation being determined by the thickness of the fan-shaped beam. 2. The method according to claim 1, characterized in that the rotation takes place about an axis of rotation which lies within the object. 3. Device for the tomographic examination of an object, with a detector, an X-ray source for projecting a fan-shaped beam against the object to be arranged between the radiation source and the detector, in order to irradiate a layer thereof, with means for optically and / or electronically coupled to the detector Generation of an electrical signal which carries the information derived from the X-ray image falling on the detector surface about the radiation of the source absorbed by the layer, with means for further processing the signal into a tomogram of the layer, and with means for relative rotation of the object with respect to the source and the detector about an axis running perpendicular to the plane of the fan-shaped beam, the device serving to carry out a method in which the object to be examined is arranged between the x-ray source and the detector surface, a layer of the ob projected from this radiation source onto the detector surface, while the object and the x-ray source with the detector surface are rotated relative to one another about an axis perpendicular to the x-ray beam emitted by the x-ray source, the images appearing one after the other on the detector surface are converted into signals which differentiate the x-ray absorption image of the layer Directions correspond, and these signals are processed to form a tomogram of the layer, and which is characterized in that the rotation takes place about an axis of rotation which intersects the fan-shaped X-ray beam at a point which is at least approximately on one of the two diverging side edges of the fan-shaped X-rays -bundle lies, so that essentially only that part of the layer is projected, which is located on one side of the axis of rotation, the thickness of the layer in the direction of the axis of rotation by the thickness of the fä cher-shaped beam is characterized, characterized in that the detector surface is dimensioned so that it captures the entire beam and the axis about which the rotation takes place intersects the x-ray beam at a point which is at least approximately at one of the two diverging side edges of the fan-shaped beam lies so that the entire layer of the object is irradiated by a complete, relative rotation of an object. 4. The device according to claim 3, characterized in that the x-ray source has a line-shaped focus directed parallel to the axis of rotation. 5. Device according to claims 3 and 4, characterized in that the detector surface is constructed as a two-dimensional matrix of discrete X-ray detector elements. 6. Device according to claims 3 and 4, characterized in that the detector surface consists of a continuous, two-dimensional X-ray screen. 7. Device according to claims 3, 4 and 6, characterized by lens, mirror or fiber optic means to image the detector surface on the photocathode of a brightness amplifier tube. 8. Device according to claims 3, 4 and 6, characterized in that the detector surface is located within the piston of an X-ray image intensifier tube. 9. Device according to one of claims 5 to 7, characterized in that the x-ray source has a line-shaped focus directed parallel to the axis of rotation and the detector surface is designed as a cylinder jacket section, the cylinder axis corresponding to the line focus of the x-ray source. 10. Device according to one of claims 3 to 9, characterized in that the set consisting of X-ray source and detector surface is stationary and means are provided to rotate the object. 11. Device according to one of claims 3 to 9, characterized in that the object is stationary and means are provided to rotate the set consisting of the X-ray source and the detector surface. 12. Device according to one of claims 3 to 11, characterized in that means are provided with which the location of the disk-shaped object cross-section can be adjusted relative to the set consisting of the X-ray source and the detector surface. The inventions relate to a method for producing a tomogram according to the preamble of patent claim 1 and a device for tomographic examination of an object according to the preamble of patent claim 3. Tomography is used particularly in the medical field, but also in workpiece and material control, e.g. used in the inspection of welds. When producing a tomogram, it is essential that each element of the cross section of the examined object can contribute to the absorption of the X-rays. If this is not the case, the information is incomplete and an exact image reconstruction is then not possible. A large number of detectors can be used to achieve this purpose, or a number of detectors can have a translational movement carried out in addition to a possible rotational movement. It is clear that such a combined movement is time consuming while also complicating the construction. The construction mentioned with a stationary row of discrete detectors has the disadvantage that the compromise between resolution and the computing time required for the image construction is only optimal for one size of the cross section; when the distance between the object and the row of detectors varies, the computing time does not change, but the resolution, however, changes as a result of a varying geometric magnification in a diverging x-ray beam. 2nd 5 10th 15 20th 25th 30th 35 40 45 50 55 60 65 630 176 The inventions aim to provide a method and a device which do not have the disadvantages mentioned above and which also offer some further advantages, such as e.g. a cheap construction, a fast and reliable effect, a low radiation dose, etc., which advantages will be discussed later. This object is achieved according to the inventions in procedural terms by the features specified in the characterizing part of claim 1 and in terms of the device by the features listed in the characterizing parts of claim 3. The device according to the invention is in particular also for medical use, i.e. the production of tomograms of the human body, determined and it is used to carry out a new method, which is characterized by the method features specified in the preamble of claim 3. According to the invention, the x-ray source can have a line-shaped focus directed parallel to the axis of rotation. According to the invention, the detector surface can be constructed as a two-dimensional matrix of discrete X-ray detector elements, to which matrix electronic means are coupled, with which the detector elements can be scanned one after the other, after which the signals thus obtained can be processed further. According to the invention, it is also possible for the detector surface to consist of a continuous, two-dimensional X-ray screen. According to the invention, lens, mirror or fiber optic means can be present in the latter embodiment to image the detector surface on the photocathode of a brightness intensifier tube. The detector surface can be located within the envelope of a direct X-ray image intensifier tube. According to the invention, the detector surface can have the shape of a part of the jacket of a cylinder, the axis of which preferably corresponds to the line focus of the X-ray source. According to the invention, means for generating the rotational movement can be present in order to rotate the object about the axis of rotation relative to a stationary set of x-ray source and detector surface. Means can also be provided to rotate the set of x-ray source and detector surface around a stationary object. The axis of rotation is preferably within the object. Finally, means can be provided with which the position of the desired object cross section can be set in relation to the set of x-ray source and detector surface.