DE4140631C1 - Computer tomograph system - rotates source around circular track around body and swings source so that beam is sent out at different distances to the body centre - Google Patents

Abstract

Between the source and detector is located the body of a patient within a radius (R). A control circuit is provided for the positioning of source, body and detector. The source is positioned along a circular track of radius r around the body, in a number of positions. The control circuit uses the following to position source, body and detector field: B = j x b A = l x A + (j mod M) x C + d where B is the position of the source on a circular track. A is the angle between a central beam running from the source (Q) to the centre of the circle, and the course of each beam spread from the source mod M is the remainder from the division of j by m; j = 1,2 .. and b = 360 degs./P p is the number of measurement positions of the source around the circle, and is selected as an odd number. The spread angle A for each individual beam is determined from the sum of three angles. a = angle between 2 neighbouring detector cells M = number of different spread angle which the detector field captures relative to the source c and d are determined from the selected geometry r/R of the computer tomograph.

Description

The invention relates to a computer tomograph according to the preamble of claim 1.

Such devices for imaging bodies are currently for example in used in medical computed tomography (see e.g. J. Gambarelli et. al .: Whole body computer tomography, Springer 1977).

Because X-rays are used as the radiation form become and a sufficiently good resolution a large number of rays have to be emitted, This results in a correspondingly high load through x-rays for the patient.

With the so-called "Flying Spot Technique", the Radiation source relative to the detector or to the Detector field to be moved. In this way, the Number of detectors can be reduced, given what the cost of the detectors and the technical conditional minimum size of the detectors to simple technical way and at low cost results in relatively high resolution. goal of "Flying spot technique" is therefore a reduction the mechanical effort that leads to good results leads as long as the number of irradiations is sufficient is great.

In contrast, the invention is based on the object with a reduced number of measurements to achieve a good resolution so that at a given resolution the number of measured values should be as small as possible is.  

This task will solved according to the invention according to claim 1.

The invention proposes a device in which two Superimpose movements before the next radiation he follows. Apart from that the source is on a path around the body is additional a pivoting between the detector field and Source made. Through this pivoting changes the angle of incidence with which the Source shines into its trajectory. It can the source or the detector field can be pivoted or the beam path from the source to the detector field, e.g. B. changed by means of an aperture will.

The source is advantageously on a circular path led around the body. Here is the body arranged within an inner circle.

The invention is based on the Representations explained in more detail below. Here shows

Fig. 1 shows a basic arrangement for explaining the operation,

Fig. 2 shows schematically a possible component for use in an arrangement according to Fig. 1,

Fig. 3 different rays at different positions of the source to the body and

Fig. 4 to 8 the comparison between the present invention by radiation results with conventional results, wherein the representations based created by computer simulations.

In Fig. 1, R denotes a circle in which a body to be irradiated, for example a human body of a patient, is arranged. The center of this body (and in the following, the entire body is simplified) is denoted by K.

Concentric around the circle with radius R is a outer circle with the radius r arranged. On a radiation source Q runs around this circle Body.

The source shines in a circle and shown as an arrow, whereby this Beam representative of a large number of fan-shaped emerging discrete rays is shown.

The beam can pass through the two sizes A and B. be characterized. B denotes the position the source Q on its circular path through the Angle between the source Q and the X axis, where the center of the two concentric circles as Coordinate origin is assumed. A denotes the angle between one - in practice not occurring - central beam of the source to the coordinate origin on the one hand and the actual Beam path on the other hand.

According to the invention, the source Q is used before a new one Radiation of the body K both in one around the Body K guided rotational movement on the circle  with the radius r moved, this change of the position angle B is referred to as the change in angle b becomes. This movement of the source Q becomes one second movement overlaid by the source Q pivots is, so that there is a change in angle c the swivel angle A of the entire beam fan results.

The described pivoting movement of the source Q is given as an example. The changed one is decisive Angle of radiation of the fan of the source Q onto the detector surface. Here - as described - the source Q, i.e. H. the individual rays emanating from the source are pivoted. However, it is also possible that the detector surface is pivoted around the source Q. After all it is possible, with the aid of an aperture, with which the discrete beams can be generated, at the same time as one another aligned source Q and detector area a different course of the rays through manipulation to cause the aperture so that this the same effect is achieved as if the radiation source opposite the detector surface would be pivoted.

In FIG. 2, an arrangement is shown schematically, which consists of the source Q and a detector array D, the source Q and the detector array D are disposed on a common frame. Two holding arms run from the source Q to the detector field D. This frame is so large that the body K is arranged between the source Q and the detector field D. The rotational movement of the source Q takes place in that this entire frame is pivoted about an axis of rotation which runs through the center of the body K. For reasons of clarity this shown in FIG. 2 is a schematic arrangement of source and detector array in Fig. 1 is not shown.

The detector field D consists of several individual detector cells, which are indicated in FIG. 2. The angle between two adjacent detector cells is denoted by a, this term being used in the formulas listed below. The angle a is measured from the source Q.

Fig. 3 shows in individual steps, the inventive arrangement of beams for creating a radiation image. Four positions of the source Q are shown on the circle with the radius r and identified by the designations Q₁, Q₂, Q₃ and Q₄.

Located at the center of the circle with radius r the body K. The starting from position Q₁ The beam from the source Q runs past the body K, whereby this distance is referred to as Z₁.

In the second position Q₂, the source Q is opposite the angular position B₁, which is the source in its Position Q₁ had to change the angle b rotates. At the same radiation angle A should be give the same distance Z of the beam from the body K. However, the source Q is not just about that Coordinate origin rotates, but also the discrete rays emanating from it are pivoted, so that from the second position Q₂ emitted beam with a larger distance Z₂ am Body blasted past. An even greater distance Z₃ from the body K indicates the beam that the Sends source of their position Q₃. Accordingly  here the swivel angle A is greater than in the two previous positions Q₁ and Q₂ the source Q.

In the fourth position Q₄ is the swivel angle A as large as in the first position Q ₁ Source Q. Hence the same distance of the Beam from the body K as in the first beam. Therefore, the distance Z₁ is as large as that Distance Z₄.

Especially when considering the following An alignment for the rays is used for the parameter Radiation through a body achieved at one considerably smaller number of rays for one good resolution and therefore good image results are sufficient:

B = j _* b and
A = 1 _* a + (j mod 3) _* c + d

As already described, B denotes the Position angle of the source Q, and b denotes the Angle change of this position.

j denotes numbers from zero to p -1, where p is the Number of measuring positions of the source in a radius represents and advantageously chosen odd becomes. j can also run from 1 to p, where in in this case only the starting point is moved by a source position. Any similar changes in the starting position are possible.  

A denotes - as already explained above - the Swivel angle, where a is the change of this swivel angle designated.

l represents changing numbers with values from -q to q-1 represents the number of detectors used 2 q corresponds.

c corresponds to -b; and d = 1/4 b · b results in 2 _* π / p and a = 3 _* b.

The information given above applies to the ratio r / R = 3. This results in a multitude of values for b or for a depending on the respective used parameters. In general, the expression in brackets (j mod 3) to be replaced by the general valid bracket expression (j mod M), where for different geometries the following values apply:

In the prior art, for example in the "Somatom" device from Siemens, the source runs exactly once around the object and the rays cover the entire object lying in a circle of radius R. The radiation therefore consists of a total of 2 _* p _* q rays, where p and q determine the resolution of the scanner. In the high-resolution mode, p = 720, q = 256, so that a total of 368 640 rays result during one revolution.

In contrast, in the case of the invention Device for an almost equal number from rays (namely 369 018 rays) p to 3231 and q to 57. Half the number opposite the state of the art is obtained with the invention Device if p = 2265 and q = 40 to get voted. A quarter of the number of rays compared to the prior art, namely 93 786 Rays are obtained at p = 1617 and q = 29.

Fig. 4 to 8 show computer-simulated results, in which Fig. 4 shows the original of a computer-simulated test body.

FIG. 5 shows the image that results from computer-simulated radiation according to the prior art when using 368,640 beams.

In contrast, FIGS. 6 to 8 show computer-simulated image reproductions as can be achieved with a device according to the invention for irradiating the test body. 6,369,018 beams were simulated for the illustration in FIG . In the illustration according to FIG. 7, 181,200 beams were simulated and FIG. 8 shows the result obtained with 93,786 beams.

The radiographs were simulated for two different density windows, whereby a density range from 990 to 1010 was selected for Fig. A, while Fig. B shows a density range from 1990 to 2010.

From the comparison of the two representations 4, the reproduce the original of the test body, the Structure of this test body can be seen. It deals is an elliptical ring of density 2000, the interior of which is 1000 in the background Has. Against this background stand out in the lower Area of the test body nine equally large circles of densities 1001 until 1009. They are used to examine the Density resolution. In the upper area of the test body there is a rectangle with density 2000 with Different diameter bores. These holes are used to investigate the spatial resolution.

The comparison of the different figures becomes clearly that compared to conventional resolution a similar or even slightly improved one Resolution with only a quarter of the number of rays possible by the device according to the invention becomes. In a medical application this a reduction in radiation exposure for the patient at 1/4 of the usual dose today significant.

Conversely, using the almost identical number of rays (see FIGS. 5 and 6) results in a considerably better reconstruction of the test body than in the conventional procedure.

Claims (2)

1. computer tomograph with a radiation source and with a detector field,
wherein a body to be irradiated can be arranged within a region with the radius R between the source and the detector field, and also with a control circuit for positioning the radiation source, body and detector field relative to one another,
the source and body being positioned relative to one another, the source is positioned in a plurality of positions along a circular path with the radius r around the body,
characterized in that the control circuit controls the positioning of the source (Q), body (K) and detector field (D) relative to one another according to the following requirements: B = j × b; andA = 1 × a + (j mod M) × c + d, where B describes the position of the source Q on a circular path, and
where A describes the angle between a central beam, which runs from the source Q to the center of the circle, and the course of each beam of a fan, which is emitted by the radiation source
with j and mod M as the remainder that remains when j is divided by M (e.g. 7 mod 4 = 3),
with j = 1, 2,. . ., p;
and with b = 360 ° / p;
where p represents the number of measuring positions of the source in a circumference and is chosen odd;
and the swivel angle A is determined for each individual beam by the sum of three angles,
with l = -q,. . . q-1;
2 × q = number of detectors used,
a = angle between two adjacent detector cells (measured from source Q); and
with M = number of different swivel angles that the detector field takes up relative to the source Q and
with c and d as angles, which are determined by the selected geometry r / R of the computer tomograph. 2. Computer tomograph according to claim 1, characterized in that, depending on the geometry of the computer tomograph, which is determined by the ratio r / R, the following values apply to the sizes a, c, d and M: