NL8700781A - METHOD AND APPARATUS FOR CONTRAST HARMONIZATION OF A ROENTGEN IMAGE. - Google Patents

Description

t * VO 9105

Title: Method and device for contrast harmonization _ of an X-ray image ._________

The invention relates to a method for contrast harmonization of X-rays of a body with a locally varying X-ray transmission, manufactured with a slit radiography device, which is provided with a slit diaphragm by means of which a body with a flat fan-shaped X-ray beam is scanned, and of at least one controllable absorber co-operating with the slit diaphragm, with which the fan-shaped X-ray beam is influenced per sector, which absorber is controlled in dependence on the amount of radiation transmitted through the body, per sector, such that at a first threshold value increasing value of the current transmission of the body occurring in a particular sector, the amount of radiation transmitted through the absorber in that sector is reduced, as well as on a slit radiography device adapted to make harmonics first X-rays.

A general problem in X-ray imaging is that the dynamics of the radiation incident on the X-ray detector are greater than the dynamics of the available imaging agents, in particular of X-ray film.

For example, when making chest X-rays, the variation in the transmission of the throax for X-rays is much greater than can be represented by the X-ray films commonly used for X-rays.

The result is that in many cases multiple X-rays are required to properly examine the different parts of the thorax. If a picture is taken such that the lungs are shown with a good contrast display, the abdomen area is often hardly more distinguishable. However, if the image is taken in such a way that both the lungs and the abdomen area are clearly visible 8'0 C '81% * 4 · -2-, the contrast display is unsatisfactory.

This is also related to the choice of film, the development method and the setting of the X-ray tube.

Obviously, taking multiple images also leads to a higher radiation load for the patient.

Attempts have already been made in the past to overcome the above-described problem. For example, in Dutch patent application 8401411 a device for slit radiography is described, with the aid of which the thorax of a patient, or another body part or object to be examined, is scanned with a flat fan-shaped X-ray beam transmitted through a slit diaphragm in a direction transverse on the longitudinal direction of the slit of the slit diaphragm. Furthermore, an absorption device co-operating with the slit diaphragm is provided, with absorption elements which, under the influence of detection means, which at any time in each sector of the X-ray beam detect the amount of radiation transmitted through the patient, are electrically generated during detection. X-rays are controlled to locally adjust the amount of radiation reaching the patient or object to the patient's transmission on site.

In this way, the dynamics in the radiation transmitted by the patient (or the object to be examined) can be adapted to the dynamics of the available imaging means. This technique is called contrast harmonization.

According to the technique described in Dutch patent application 8401411, the absorption elements are controlled such that above a certain value of the quantity of X-rays locally transmitted by the patient or the object, the associated absorption element (s) is always which corresponds to the exposure of the image-forming means associated with the said determined value.

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In a practical situation, this means that the exposure of the image-forming means, such as an X-ray film, increases from a low value to a predetermined value of the patient transmission proportional to the patient transmission, and remains constant with further increasing values of the patient transmission. This results in X-rays of which the average gray value of each region corresponding to an absorption element is substantially equal to that of any other region corresponding to an absorption element. In such a photograph details which fall within an area currently covered by an absorption element are clearly visible, but contrast differences occurring over larger areas, which occur for instance with pneumothorax and some large tumors, are difficult to distinguish.

Also, such photos are somewhat unnatural, because the local blackening is no longer proportional to the local patient transmission.

There is therefore a need for a harmonization method, which leads to more natural recordings, and to recordings, which make it possible to properly observe contrast differences over relatively large areas.

The object of the invention is to meet this need and in general to provide a reliable and effective method for contrast harmonization of an X-ray image. For this purpose, according to the invention, a method of the type described is characterized in that above the threshold value at least in regions of transmission values relevant for the X-ray recording, a higher transmission value leads to a predetermined extent to a substantially higher amount of radiation transmitted through the body.

A slit radiography apparatus adapted to make harmonized X-rays and comprising an assembly of an X-ray source and a slit diaphragm for the formation of a flat fan-shaped X-ray beam by means of which a body can be scanned, an X-ray detector for collecting radiation transmitted through the body, at least one absorber placed near the slit diaphragm-5 ma and which can currently influence the amount of X-rays transmitted through the slit diaphragm per sector of the fan-shaped beam under the influence of suitable control signals, detection means, which, per sector of the fan-shaped beam, detect the amount of X-ray radiation transmitted by the body and supply an input signal to a control device which forms control signals serving as the absorption device, which control device is adapted to operate from a first threshold value from d According to the invention, the amount of radiation transmitted by the body in a particular sector to form a control signal which controls the absorber in such a way that the amount of radiation offered in that sector is partially absorbed, is characterized in that above the threshold value at least for the X-ray image relevant areas of the value of the amount of radiation transmitted through the body, a higher value corresponds to a predetermined degree to a substantially higher on-site transmission.

In the following the invention will be further elucidated with reference to the attached drawing.

Figure 1 schematically shows a device for slit radiography in side view; Figure 2 shows an example of a control circuit suitable for a control according to the invention of absorption elements shown in Figure 1; Figure 3 illustrates the invention a graph of the relationship between screen dose and patient transmission, respectively, film blackening; Figure 4 and Figure 5 show details of a modification of an apparatus according to the invention.

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Figure 1 shows schematically, in side view, a device for slit radiography. The device shown comprises an X-ray source 1 with an X-ray focus F. A slit diaphragm 2 is placed in front of the X-ray source, by means of which a rather flat, fan-shaped X-ray beam 3 is formed, which is aimed at an X-ray detector 4. As shown in Fig. 1, although the X-ray beam 3 is somewhat wedge-shaped in side view, the height at the location of the X-ray detector is small, for example 3 cm, while the width of the beam perpendicular to the plane 10 of the drawing can be, for example, 40 cm, so that it is generally referred to as a flat X-ray beam.

The X-ray source and the slit diaphragm can move together such that the X-ray beam makes a scanning movement transverse to the width direction of the beam, ie vertically in the plane of the drawing, as indicated by a double arrow 5. Such a scanning movement can be easily accomplished by the x-ray source and slit diaphragm assembly to pivot an axis extending transversely to the plane of the drawing through the x-ray focus F, as indicated by an arrow 6. A flat fan-shaped beam performing a scanning movement however, it can also be obtained in other ways, such as, for example, indicated in Dutch patent application 8401411.

In the example shown, the X-ray detector 4 is a conventional large-screen cassette, which is exposed in the vertical direction during the scanning movement of the X-ray beam in strips. Instead of such a stationary large-image cassette, a strip-shaped X-ray detector could also be used, which converts the incident X-rays into a strip-shaped light image, which in turn is used to make a photographic film. e r v>. ' * Μ -6- exposure. An example of such an application of a strip-shaped X-ray detector is shown in Dutch patent application 8401411.

In order to be able to control the amount of X-rays supplied to a patient or an object 7 to be examined at a given moment and in a certain sector of the X-ray beam, thereby also controlling the exposure of the corresponding part of the X-ray detector, an absorption device 8 is placed in the X-ray beam near the slit diaphragm 2. The absorption device is arranged in such a way that under the influence of suitable control signals per sector of the X-ray beam and at any moment the amount of radiation transmitted can be controlled.

Some examples of suitable absorbers are described in Dutch patent application 8400845.

In Fig. 1, by way of example, a plurality of juxtaposed tongues 9, one of which is visible, is shown comprising absorption device. The tongues 20 have free ends which can be introduced into the X-ray beam to a greater or lesser extent under the influence of control signals, in order to absorb a part of the X-rays.

The control signals for the absorber are provided by a control circuit 10. The control circuit 10 receives input signals from a detection device 11, which currently detects the amount of X-rays transmitted by the patient or the object 7 per sector of the fan-shaped X-ray beam and corresponding 30 electrical output signals.

The detection device can be located between the patient or the object and the X-ray detector 4, as shown in figure 1, but in principle it can also be behind

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% «* * V 1 -w: ¥ * * -7- the X-ray detector 4. In both cases, the detection device can either respond directly to incident X-rays or to light radiation generated by the X-ray detector in response to incident X-rays.

If the detection device is located between the patient or the object 7 and the X-ray detector 4, the X-ray detection device should be as transparent as possible so that the final X-ray image 10 is affected as little as possible by the detection device. Suitable detection devices are described, for example, in Dutch patent application 8503152 and in Dutch patent application 8503153.

Figure 2 shows an example of a control circuit 10 suitable for application of the invention. The control circuit 10 forms a connection between the detection device and the absorption device and in principle comprises corresponding sections of the detection device for each set and the absorber has an associated dividing circuit. Only one of these partial circuits is shown, which will be referred to as control circuit for the sake of simplicity in the following. It is noted that in practice some parts of the control circuits can be used jointly for all sub-circuits using multiplex techniques.

The control circuit shown in Figure 2 is substantially the same as the control circuit shown in Dutch patent application 8401411. The control circuit 10 receives, on the one hand, via a line 20, input signals from a section of the detection device and, on the other hand, provides output signals via a line 21 to a corresponding section of the absorption device. The control circuit 87 7 7; :

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-8- comprises a comparison circuit, which in this example comprises a reference amplifier 23. A signal 5 proportional to the input signal of the control circuit is applied to one input of the reference amplifier via a line 24 and to the other input a reference signal, which in the example shown is provided by a potentiometer 25. The output signal of the amplifier 23 corresponds at least in polarity with the difference between the signals applied to both inputs. The output of the amplifier 23 is connected to the input of an amplifier 26, which, depending on the type of absorber used, can be a voltage amplifier or a current amplifier, and which is one for controlling the relevant section of the absorber 15. suitable output signal. This output signal controls the absorber so that the difference between the input signals of the reference amplifier is reduced to zero. In the example shown, the control circuit 10 further comprises an input amplifier 27, the output signal of which is applied to the reference amplifier 23.

The control circuit described so far corresponds to the circuit shown and described in Dutch patent application 8401411. The use of such a circuit independently of the transmission leads to a constant average gray value (optical density) of the final X-ray image over each area affected by a particular section of the absorber. This gray value depends on the setting of the potentiometer 30 meters. If the potentiometers 25 of all partial circuits have the same setting, the final X-ray exposure therefore averages this gray value over the entire image plane.

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As noted above, in certain situations there is a need to be able to properly observe contrast differences between relatively large parts of the X-ray image. According to the invention, this need can be met by controlling the absorption elements of the absorber in such a way that the difference between the input signals of the reference amplifier is not completely eliminated, but a certain proportionality between the local patient transmission and the local gray value of the X-ray image is maintained.

For further explanation, reference is made to Figure 3. Figure 3 shows in the right part the relationship between the patient transmission (or object transmission) T for X-rays, plotted along the horizontal axis, and the screen-dose S, plotted along the vertical axis. The screen dose is the amount of X-rays that reach the X-ray detector.

The left part of figpur 3 shows the relationship between the screen dose and the resulting gray value 20 (optical density D) of an image on an X-ray film.

The graph shown relates to a so-called reversal film, which forms a light image with low exposure (after development of the film) and which forms a dark image with strong exposure, and thus with a high X-ray dose. However, the invention is equally applicable when using other film types or other imaging agents.

In the right part of figure 3 a thorax is further schematically illustrated for illustrative purposes. The lung area 30 is indicated by I and the abdomen area is indicated by II.

The lungs are the most transparent to X-rays, and the abdomen is the least transparent. For illustrative purposes, the graphs show the corresponding patient transmission

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-10 regions and the optical density regions, respectively, also indicated by I and II.

The right part of Figure 3 shows a number of characteristics 30, 31, 32 and 33. Characteristic 30 indicates the relationship between the patient transmission and the screen dose in the absence of any influence on the scanning X-ray beam during an exposure. The characteristic 30 is therefore essentially a straight line. It can be seen that the patient transmission in the abdomen region 10 (hatched region II) corresponds to a screen dose region, which again corresponds to a density region D1 of the film used. Although the area D ^ does not fully fall within the optimum working area of the film indicated by W, in which the characteristic characteristic of the film shown 34 is substantially linear, it is clear that the area corresponds to a relatively wide area D ^, so that the contrast display in this area is good.

On the other hand, the patient transmission in the lung region (shaded region I) is much greater at the same setting of the X-ray source and corresponds to a screen dose region S ^, which again corresponds to a density region D ^. However, the screen dose area is far outside the optimum working area of the film, so that at a screen dose in this area an overexposure of the film occurs. The result of this is a very dark image with, moreover, a poor contrast reproduction, as may be seen from the relatively small width of the area ° 2 '30. The graphs shown may show that due to the large difference in transparency of the lungs and the abdomen is not simply possible to display both the lungs and the abdomen sufficiently clearly and with sufficient contrast on one and the same image.

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The solution to this problem described in Dutch patent application 8401411 is represented by the curve 31, which consists of a part 31a, which approximately coincides with the straight line 30, and a part 31b located beyond a tilting point 31c, which extends substantially horizontally. .

The portion 31a corresponds to a region of low patient transmission in which the absorber is not or hardly active. However, beyond the tilting point 31c, the control circuit formed by the detection device, the control circuit, the absorption device and the X-ray beam strives for an average gray value determined by the setting of the reference signal generator 25 (Figure 2). If the sections of the absorber (and the sections of the detector) were infinitely narrow, such control would result in a smooth gray image. However, the sections of the absorber each influence at any time an area on the X-ray detector of non-negligible dimensions, eg 4x4 cm. As a result, contrast differences within such areas remain clearly visible in the final image. As a result, contours also remain clearly visible. However, contrasts between larger areas, such as, for example, a density difference between the left lung and the right lung, such as can occur with pneumothorax, are not visible. One speaks of full harmonization. Furthermore, in this situation, the lung-displaying part of the final radiograph is not very natural, which can be felt as a drawback. On the other hand, overexposure is excluded with this control method.

According to the invention, use is now made of a control curve, as shown at 32, the portion of which beyond a tilting point, which in turn may be the tilting point 31c, has a slope which is between that of line 30 and fc ': -12 the horizontal part 31b of the curve 31 lies in. When such a control curve is used, the natural character of the final X-ray image is maintained, because a larger patient transmission leads to a higher film-blacking, while overexposure can nevertheless occur. Indeed, the patient transmission region corresponding to the lung region I corresponds to a screen dose region at the curve 32, which falls within the working region W of the film, and which results in a film blacking in the density region D1.

Such a control curve is obtained in the control circuit of Figure 2 not to fully reset the difference between the input signals of the reference amplifier to zero. All this can be accomplished practically by designing the amplifier 26 with a gain control device 28. The set gain determines the slope of the control curve 32 beyond the tilt point. More generally, the slope of the control curve 32 can be adjusted by an appropriate adjustment of the circular gain in the circuit formed by the X-ray beam, the detection device, the control circuit and the absorber.

Furthermore, the X-ray source must, of course, be adjusted in such a way that even in the least transparent part of the patient or object there still occurs a screen dose of 25, such that this part and the contrasts occurring therein can still be properly represented by the film. In practice, this means that when making a harmonized chest image, a higher X-ray tube current is used than is normally used. For example 125 mA instead of 30 mA.

It is noted that the function of the described control circuit can also be performed by a suitably programmed microprocessor.

The described control method can still be modified in such a way that it fits with the lung region I of a 7 ° C. 4 -13- patient corresponding patient transmission area within the film operating area W with a better contrast display than is shown in the control curve 32.

Figure 3 clearly shows that the contrast representation of the lung region I is better the steeper the control curve 32. After all, the associated screen dose area then becomes larger, and thereby also the associated density area D1. However, if to achieve this effect the angle of inclination of the curve 32 is chosen larger by an appropriate adjustment of the gain control of the amplifier 26, the corresponding screen dose range shifts beyond the operating range W of the film. Thus, a steeper course of the control curve 15 within the patient transmission region corresponding to the lung region I must be accomplished in other ways.

According to the invention the absorption device can for this purpose be arranged such that the absorption elements can influence the slit of the slit diaphragm only over a predetermined part of the height of the slit. This can be accomplished, for example, by using a mechanical stop for the absorption elements, which prevents the absorption elements from completely closing the slit diaphragm. A similar effect can also be achieved electronically or by appropriate programming of a microprocessor controlling the absorption elements.

A suitable mechanical stop can be constructed in many ways depending on the type of absorption elements used. When hinged tongue-like absorption elements or sliding elements are used, a cord or the like can be used which is connected to an absorption element and limits the deflection thereof. All this is shown in figure 4.

The cord is indicated at 40 in the tensioned state and at 40 'in the rest state. In figure 4 it can be seen that the slit S of the slit diaphragm 2 always remains free over a part "a" of the total height.

A similar effect can be obtained by using a stop 50, as shown in Figure 5. Since the stop is in front of the slit S, the X-ray stop 10 should be transparent. The stop can for instance be made of perspex.

By using such a mechanical stop or its electrical equivalent, a control curve of the type indicated at 33 in Figure 3 is obtained. This curve comprises a first portion 31a, which coincides with that of the curve 31, in which the absorber is not yet or hardly active and in which the screen dose increases proportionally with the patient transmission. Past the tipping point, a sloping portion 33a follows, in which the absorber operates. The angle of inclination of the portion 33a is adjustable in the manner already described.

Past a stop point 33b, a section 33c then follows, in which the absorber always has the maximum effect and the screen dose increases again proportionally with increasing patient transmission as a result of the free part of the diaphragm gap. Thus, the portion 33c is in principle parallel to the line 30. If the stop point 33b, as shown in Figure 3, is suitably selected, that is, at a value of the patient transmission, which is lower than the patient transmission in the lung region I, the screen dose increases in proportion to patient transmission throughout the lung area. The X-ray image thus has both for the abdominal area II

8? S H? - V? Preventing patient transmission values as well as for the patient transmission values occurring in the lung region I have a natural character, if at least the X-ray film used can properly process the associated screen dose values.

5 The latter is indeed the case. The screen dose area Sj has already been discussed previously and the screen dose area S ^ V corresponding to the intersections of the curve 33 with the region of patient transmission values associated with the lung region I falls substantially within the working region W of the film. A good contrast display is therefore guaranteed.

It is noted that the location of the area 1 is adjustable by the choice of the tilting point 31c, by adjusting the angle of inclination of the curve 33 beyond the tilting point 31c and by selecting the stop point 33b (setting the stop 40 or 50 ).

It is further noted that the angle of inclination of the portion 33a could be adjusted such that the portion 33a coincides with the portion 31b of the curve 31. In fact, a system of the type described in Dutch patent application 8401411 has then been created, wherein an attachment point for the absorption elements is provided electrically or mechanically.

In Figure 3, the portion 33c of the curve 33 is drawn parallel to the line 30. Theoretically, it is possible to give the part 33c a different angle of inclination. A less steep course can be obtained by effecting a certain increasing action of the absorber beyond the point of impact 33b. When using a mechanical stopper, this could be accomplished by dividing the mechanical stopper into sections corresponding to the different absorption elements, and resiliently arranging the stopper sections so that displacement is possible below. ri * -16- influence of a force exerted by an absorption element. All this can be accomplished in the configuration shown in figure 4 by including a (tension) spring in the connection 40. In a similar manner, in the configuration of figure 5, for example, a (compression) spring 51 can be used.

It is also possible to use a second absorber with associated control circuit for the part "a" of the gap S.

When using an electrical pick-up point, this can be accomplished by changing the gain of the amplifier 26 or changing the operation of a microprocessor at a screen dose higher than the screen dose associated with the pick-point 33b.

In general, however, it is more important to make the part 33c steeper than the straight line 30, because then the area S1 'is increased, which leads to an increase in the corresponding density area and thus to an improved contrast reproduction.

A steeper course of the part 33c can be obtained by decreasing the influence of the absorber, which is maximum at the point 33b, at a higher dose than the screen dose values associated with the point of impact 33b. This effect can be achieved, for example, with the aid of a suitably programmed microprocessor or electronically.

The same effect is obtained by using a second absorber, which normally closes the gap S over a certain height, but gradually opens beyond the point of attack of the first absorber with increasing screen dose.

It is noted that after the foregoing various modifications of the invention, for example of the circuit 10 or of the described stop devices, are obvious to the skilled person.

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Thus, especially when using a microprocessor for controlling the absorber, it is possible to achieve a control curve that has more than one tilt point and strike point. A similar effect can be obtained by using one or more additional absorbers controlled by separate control signals. For example, a second absorption device could be placed on the other side of the slit S and have a tipping point located beyond the stop point 33b. A stop point could then also be created beyond such a tipping point.

Such modifications are considered to fall within the scope of the invention.

Claims (23)

A method for contrast harmonization of X-rays of a body with a locally varying X-ray transmission, manufactured with a slit radiography apparatus having a slit diaphragm 5 by means of which a body with a flat fan-shaped X-ray beam is scanned, and of at least one with the slit diaphragm cooperating controllable absorption device, with which the fan-shaped X-ray beam is influenced per sector, which absorption device is controlled in accordance with the amount of radiation transmitted through the body per sector, so that at an increasing value from a first threshold value of the transmission of the body currently occurring in a particular sector, the amount of radiation transmitted through the absorption device in that sector is reduced, characterized in that above the threshold value at least in transmission value regions relevant for the X-ray image e and higher transmission value to a predetermined degree results in a substantially higher amount of radiation transmitted through the body. Method according to claim 1, characterized in that the absorber is controlled such that above a second local transmission threshold value, which is higher than the first value, the corresponding sectors of the fan-shaped beam do not exceed a predetermined maximum rates are affected by the absorber, with a predetermined portion of the fan-shaped beam still being freely transmitted in each sector. 3. A method according to claim 2, comprising the% *; "f-" i; t •; . > "O" * - 19, note that the absorber is controlled in such a way that with a local transmission increasing from the second threshold value onwards, the influence of the corresponding sectors of the fan-shaped beam decreases from the said maximum degree. 4. A method according to claim 1, characterized in that the absorber is controlled such that with a local transmission increasing from a second threshold value which is higher than the first value, the influence of the corresponding sectors of the fan-shaped beam increases to a degree other than for transmission values lower than the second threshold. Method according to any one of claims 1 to 4, characterized in that the predetermined degree in which a higher transmission value results in a substantially higher amount of radiation transmitted through the body is adjustable. 6. Method according to any one of claims 2 to 5, characterized in that the second threshold value is adjustable. 7. Slit radiography apparatus adapted to make harmonized X-rays and comprising an X-ray source and slit diaphragm assembly to form a flat fan-shaped X-ray beam by which a body can be scanned; an x-ray detector for collecting radiation transmitted through the body; at least one absorber disposed near the slit diaphragm and which is capable of affecting, per sector 30 of the fan-shaped beam, the amount of X-rays transmitted through the slit diaphragm under the influence of suitable control signals; detection means, which per sector of the fan-shaped beam detect the amount of X-ray radiation transmitted through the body at a time of fr. 7 f; * 1 · VA 1 -20- * and supply an input signal to a control device which forms control signals serving as absorbers for the absorber device, which control device is adapted to start from a first threshold value of the quantity transmitted by the body in a certain sector radiation to form a control signal which controls the absorption device in such a way that the amount of radiation offered in that sector is partially absorbed, characterized in that above the threshold value at least in areas relevant to the X-ray image of the value of the radiation the amount of radiation transmitted through the body, a higher value predetermined to correspond to a substantially higher transmission on site. 8. Device as claimed in claim 7, characterized in that the control device has a suitable function. programmed microprocessor. 9. Device according to claim 7 or 8, characterized by means for adjusting the circumferential gain in the circuit formed by the X-ray beam, the detection means, the control device and the absorption device. 10. Device according to claim 7 or 9, characterized in that the control device comprises a comparison circuit which can compare an input signal with a predetermined reference signal, which represents said first threshold value; and that the output of the comparator circuit is connected to an amplifier, the gain of which determines said predetermined degree of absorption. 11. Device according to claim 9 or 10, characterized in that the amplification factor is adjustable. 12. Device as claimed in any of the claims 7-11, having "N \ ft. - - *" /, V ·. f -21- characterized in that the control device is arranged to control the absorption device 5 from a second threshold value of a higher than the first threshold value of the amount of X-rays transmitted through the body in a sector, such that in that sector no more than a fixed maximum part of the X-rays is absorbed and the rest of the radiation offered in that sector is let through. Device as claimed in claim 12, wherein the absorption device comprises absorption elements which co-act with a slit of the slit diaphragm, the absorption elements under the influence of the signals from the control device to a greater or lesser extent in a direction transverse to the longitudinal direction of the slit in front of the slit can be moved, characterized in that said second threshold value corresponds to an extreme position of an absorption element, in which the slit remains free over a predetermined height. 14. Device. according to any one of the preceding claims 7 to 20 13, characterized by means which, at least in certain areas of the value of the amount of radiation currently transmitted by a body in a certain sector, relate the relationship between the control signals and the response in response to the control signals. the absorber can alter the influence of the X-ray beam caused. Device according to claim 13 or 14, characterized in that the absorption device is provided with at least one stop member which determines the extreme position of an absorption element. Device according to any one of claims 7 to 11 or 14, 15, characterized in that the control device is adapted to absorb the absorption of the amount of X-rays transmitted through a body from a second threshold value higher than the first threshold value. - P. 7! \ F: "·: y, 1 tvj ·. R» * V "* -22- * device to be controlled in such a way that of the quantity of radiation offered in that sector the part corresponding to the second threshold value in a predetermined fixed amount is absorbed and the residual radiation offered in that sector 5 is absorbed in a predetermined second degree. 17. Device as claimed in claim 15, characterized in that the stop member comprises for each absorption element a separate stop which can be moved through the absorption element with a predetermined resistance. 18. Device as claimed in claim 17, characterized in that the stop member for each absorption element comprises an X-ray transparent member, which is forced into a predetermined rest position under the influence of resilience, which corresponds to a specific deflection of the absorption element. and which can be moved out of its rest position against the spring force by the absorption element. Device according to claim 17, characterized in that the stop member for each absorption element has a resilient element comprising a flexible connection between a fixed point and the absorption element. Device according to any one of claims 12 to 15, 25, characterized in that the control device is adapted to control the absorption device in such a way that, at an increasing value from the second threshold value, the value passed through the body in a sector amount of X-rays, the absorption from the maximum portion corresponding to the second threshold value decreases proportionally. 21. device according to any one of claims 7 to 20 inclusive, characterized by at least a second absorption device which is controlled by the control device. 1 * '/ - ^ <-23- £ 22. Device as claimed in claim 21, characterized in that the control device is adapted to activate the second absorption device from a rest position if the amount of X-rays transmitted by a body in a certain sector is greater than a predetermined third threshold value. 23. Device according to claim 22, characterized in that the third threshold value is equal to the second threshold value. F * 'Ί i -1 i