DE102009049052B4 - Computed tomography device with a device for data transmission and method for data transmission in a computed tomography device - Google Patents

Abstract

Computed tomography device (1) with a gantry (2), having a stationary part (3) and a rotatable part (4), which rotatable part (4) around a disk-shaped or cylindrical measuring field (12) when the computed tomography apparatus (1) is in operation which a measurement object (P) can be arranged, rotates, in which for a data transfer from the rotatable part (4) to the stationary part (3) and / or for a data transfer from the stationary part (3) to the rotatable part (4) on the stationary part (3) or on the rotatable part (4) at least one first directional antenna (26, 29, 52, 55) having a directional characteristic is arranged, the directional characteristic of which is used to suppress multipath reception within the gantry in the direction of at least a second directional antenna ( 26, 29, 52, 55) cooperating antenna (21, 42, 45) arranged on the rotatable part (4) or on the stationary part (3) is electronically adjustable, the directional characteristic of the at least one first Directional antenna (26, 29, 52, 55) is set electronically in such a way that the data transmission between the at least ...

Description

The invention relates to a computed tomography device with a device for data transmission and to a method for data transmission in a computed tomography device.

A third generation computed tomography apparatus includes a gantry having a stationary portion and a rotatable portion which, during operation of the computed tomography apparatus, rotates relative to the stationary portion and carries an x-ray system comprising an x-ray source and an x-ray receiver. From the stationary part to the rotatable part, status, control and regulation information is usually to be transmitted, which is not critical in terms of the amount of data. However, with regard to the control information, only a certain delay in transmission is allowed. From the rotatable part to the stationary part, in addition to status, control and regulation information, large amounts of measurement data generated by the X-ray detector are still to be transmitted. With modern computer tomography devices, data rates of several GBits / s are often required in this direction of transmission.

The data transfer between stationary and rotatable part is nowadays usually contact-related via so-called slip rings. However, contactless forms of data transmission have also been proposed. So is in the US 5,577,026 a computed tomography device is described in which the data transmission between the stationary and the rotatable part of the gantry is capacitive.

From the US 5,469,488 is a computed tomography device is known in which the data transmission between the stationary and rotatable part of the gantry is done optically.

An optical data transmission device for data transmission between a rotating part and a fixed part of a computed tomography device is also known from EP 0 381 786 B1 known. Arranged on the rotating part of the light emitter cooperate with a arranged on the fixed part of the light receiver, wherein the light emitter during rotation of the rotating part about an axis parallel to the axis of rotation are rotatable so that their light beam is mechanically trackable on the light receiver.

Another alternative is data transmission using radio technology. Such a data transmission by means of radio technology in a computed tomography device, for example, in US 6,914,957 B2 or the DE 101 50 048 A1 described.

From the DE 10 2005 026 158 A1 a device for data transmission for a computed tomography device is known, in which the transmission of data from the rotating part of the gantry of the computed tomography device to the stationary patient table of the computed tomography device takes place with a directional radio link, which is an antenna arrangement for directional transmission from the rotating part of the gantry in the direction of Includes rotation axis and a direction-selective reception of the patient table.

For a transmission with radio waves with a data rate of several GBits / s, however, a frequency bandwidth in the GHz range is required, which in turn entails a carrier frequency in the GHz range. At GHz frequencies, however, radio waves are virtually optical. In a gantry of a computed tomography device, this results in a complex reception situation in which the partial waves reflected by a transmitter arranged, for example, on the rotatable part are superimposed on the receiver arranged on the stationary part on the many metallic surfaces of the gantry. Due to the rotation of the rotatable part of the gantry this multipath reception is also variable in time.

The invention is therefore based on the object of specifying a further alternative for data transmission in a computed tomography device.

According to the invention, this object is achieved by a computed tomography device and by a method for a computed tomography device having a gantry with a stationary part and a rotatable part, wherein for a data transmission from the rotatable part to the stationary part and / or for a data transmission from the stationary Part of the rotatable part on the stationary part or on the rotatable part at least a first directional having directional antenna is arranged whose directional characteristic for suppressing a multipath reception within the gantry towards at least a second, cooperating with the directional antenna, arranged on the rotatable or stationary part antenna is dynamically electronically adjustable or trackable. By this solution, the use of high frequencies in the contactless data transmission or signal transmission with radio waves, which in the case of the present invention are preferably understood electromagnetic waves in the microwave range, within the gantry possible because of the at least one first directional antenna and the at least one second antenna formed Directional radio link a multipath reception is suppressed. The directivity of the directional antenna, ie the respective preferred direction of the directional characteristic, as well as the suppression of multipath reception are the better, the higher the carrier frequency, which is preferably in the GHz range. This is also advantageous in that a higher carrier frequency also simplifies the use of a larger frequency bandwidth.

In order to maintain the radio link or the radio link during rotation of the rotatable member relative to the stationary part, the directional characteristic of the directional antenna is dynamically electronically adjustable or trackable, so that the directivity of the directional antenna is adapted to each of the transmission situation. The directional antenna is associated with a corresponding antenna electronics.

To realize such a dynamically electronically adjustable or trackable radio link, it is sufficient, moreover, only one antenna of the radio link, be it on the rotatable part or be it arranged on the stationary part antenna as a directional antenna. The respective other antenna can have a large acceptance angle, so that a tracking of the antenna characteristic of this antenna is not required. This saves the electronics required for tracking the antenna characteristic of this antenna, but also reduces the suppression of multipath reception by the directional characteristic which is present in this case only in the case of an antenna.

During operation of the computed tomography device, the rotatable part of the gantry rotates about a disc-shaped or cylindrical measuring field in which a measurement object can be arranged, the directional characteristic of the at least one first directional antenna being dynamically electronically adjustable or trackable such that the data transmission between the at least one first directional antenna and the at least one second antenna is outside the measuring field. In this case, the transmitting antenna is preferably the directional antenna. Because the data transmission takes place outside the measuring field, on the one hand a measuring object located in the measuring field is not exposed to the electromagnetic radio waves and on the other hand the measuring object, in particular if it is a living being, does not disturb the data transmission.

According to a variant of the invention, the dynamic electronic adjustment or tracking of the directional characteristic of the at least one first directional antenna in the direction of the at least one second antenna in dependence on the rotation angle of the rotatable part relative to the stationary part. The respective rotation angle can be determined, for example, with an angle sensor of the computed tomography device and made available for the setting or tracking.

According to another variant of the invention, the dynamic electronic adjustment or tracking of the directional characteristic of the at least one first directional antenna in the direction of the at least one second antenna depending on the quality of the transmission factor between the at least one first directional antenna and the at least one second antenna. The transmission factor is understood to be the ratio of the reception antenna power to the transmission antenna power. The directional characteristic of the directional antenna is therefore always tracked when the transmission factor falls below a predetermined limit.

According to one embodiment of the invention, the at least one second antenna is also a directional antenna whose directional characteristic is dynamically electronically adjustable or trackable. The fact that the directional characteristics of the at least one first directional antenna and the at least one second directional antenna in operation generally aligns with one another results in improved suppression of multipath reception and thus improved data transmission between the rotating and the stationary part of the gantry.

The dynamic electronic adjustment or tracking of the directional characteristics of the at least one first directional antenna and the at least one second directional antenna relative to each other according to variants of the invention either again depending on the rotation angle of the rotatable part relative to the stationary part or depending on the quality of the transmission factor between the at least a first directional antenna and the at least one second directional antenna.

According to one embodiment of the invention, two data transmitters are arranged opposite each other on the rotatable part of the gantry, each of which has a directional antenna, and the stationary part of the gantry is provided with a data receiver having the at least one second antenna. Preferably, the directional characteristics of the directional antennas of the two arranged on the rotatable part data transmitter during the rotation of the rotatable part to the measuring field so dynamically adjusted or tracked that always a data transmission between at least one of the two directional antennas and the at least one second antenna of the stationary part arranged data receiver can be done. The at least one second is also preferred Antenna designed as a directional antenna whose directional characteristic is adjusted or tracked.

According to an alternative embodiment of the invention may be arranged on the rotatable part and only one data transmitter having a directional antenna, whereas on the stationary part of two data receivers are arranged opposite each other, each of which has a second antenna. The directional characteristic of the directional antenna of the data transmitter arranged on the rotatable part is set or tracked dynamically electronically during the rotation of the rotatable part about the measuring field in such a way that data is always transmitted between the directional antenna and at least one of the second antennas of the data receivers arranged on the stationary part can. The second antennas can preferably also be designed as directional antennas.

According to a further alternative embodiment of the invention, at least two data transmitters, each of which has a directional antenna, are opposite each other on the rotatable or stationary part and at least two data receivers each having a second antenna on the stationary or rotatable part arranged. Also in this case, the directional characteristics of the directional antennas of the at least two data transmitters are electronically adjusted during the rotation of the rotatable part around the measuring field such that data is always transmitted between at least one of the at least two directional antennas of the data transmitters and at least one of the at least two second antennas of the data receivers can. If the second antennas are again designed as directional antennas, their directional characteristics are likewise set or tracked accordingly.

A variant of the invention provides that a directional antenna is designed as a phased array antenna.

Embodiments of the invention are illustrated in the accompanying schematic drawings. Show it:

1 a computed tomography device,

2 to 6 Illustrations of the data transmission between rotatable and stationary part of the gantry of the computed tomography device 1 via radio relay.

In the figures, identical or functionally identical elements are provided with the same reference numerals throughout. The illustrations in the figures are schematic and not necessarily to scale. On the in 1 illustrated X-ray computer tomography device 1 is in the following and without restriction of generality only to the extent that it is considered necessary for the understanding of the invention.

This in 1 X-ray computer tomography device shown 1 includes a gantry 2 with a stationary part 3 and with one around a system axis 5 rotatable part 4 , The rotatable part 4 has in the case of the present embodiment of the invention, an X-ray system, which is an X-ray source 6 and an X-ray detector 7 includes, on the rotatable part 4 are arranged opposite one another. During operation of the X-ray computer tomography device 1 goes from the X-ray source 6 X-rays 8th in the direction of the X-ray detector 7 , penetrates a test object and is detected by the X-ray detector 7 recorded in the form of measurement data.

The X-ray computer tomography device 1 also has a patient bed 9 for storage of a patient P to be examined. The patient bed 9 includes a lying base 10 to which a patient support plate intended for the actual storage of the patient P 11 is arranged. The patient support plate 11 is so relative to the bed base 10 in the direction of the system axis 5 adjustable to put it together with the patient P in the opening 12 the gantry 4 , which in the present case defines a cylindrical measuring field, for receiving 2D x-ray projections from the patient P, z. B. in a spiral scan, can be introduced. The computational processing of the X-ray system recorded 2D X-ray projections or the reconstruction of slices, 3D images or a 3D data set based on the 2D X-ray projections is done with an image computer 13 of the X-ray computer tomography device 1 which layer images or 3D images on a display device 14 are representable.

During operation of the X-ray computer tomography device 1 are data on operating states of components, control data and control data both from the stationary part 3 on the rotatable part 4 as well as the rotatable part 4 on the stationary part 3 the gantry 2 transferred to. Furthermore, there are large amounts of with the X-ray detector 7 recorded measurement data from the rotatable part 4 on the stationary part 3 transferred to. According to the invention, this is done by means of at least one electronically adjustable or with respect to the rotation of the rotatable part 4 trackable radio link.

The 2 to 4 illustrate a first embodiment of such an electronically traceable radio link for the Data transmission between stationary and rotatable part of the gantry 2 , In the 2 to 4 is a data transfer from the rotatable part 4 on the stationary part 3 shown.

In case of in the 2 to 4 illustrated embodiment of the invention is on the stationary part 4 the gantry 2 a receiver 20 fixedly arranged for radio waves, the one schematically indicated directional antenna in the form of a phased array antenna 21 which is designed such that the directivity of the phased array antenna 21 with a corresponding antenna electronics 22 is dynamically electronically adjustable, so that the directivity can change. The directional characteristic of the directional antenna 21 is in the 2 to 4 with a fan of light 23 illustrated, which schematically, that is not exactly reproduces the actual antenna diagram or directional diagram and, as already mentioned, the illustration serves. This also applies to the other directional antennas described below.

At the rotatable part 4 are in the case of the present embodiment of the invention 180 ° opposite each other two transmitters 24 . 25 fixed for radio waves. The transmitter 24 has a directional antenna in the form of a phased array antenna 26 with assigned antenna electronics 27 on. The fan of rays 28 illustrates the directional characteristic of the directional antenna 26 , by means of the antenna electronics 27 dynamically electronically adjustable. The transmitter 25 has a directional antenna in the form of a phased array antenna 29 with assigned antenna electronics 30 on. The fan of rays 31 illustrates the directional characteristic of the directional antenna 29 , by means of the antenna electronics 30 is also dynamically adjustable electronically.

In operation, in particular in the measuring operation of the computed tomography device 1 if the rotatable part 4 relative to the stationary part 3 around the opening 12 or the measuring field 12 rotates, the directional characteristics of the directional antennas 26 . 29 the transmitter 24 . 25 and the directional characteristic of the directional antenna 21 Recipient 20 always so dynamically adjusted electronically or tracked relative to each other in their direction that between at least one of the transmitter 24 . 25 and the receiver 20 a data transmission via radio can be done. The data transmission, ie the spatial tracking of the directional characteristics, preferably takes place outside of the measuring field 12 in order not to act on the patient P with radio waves whose carrier frequency is in the GHz range or to disturb the data transmission through the body of the patient P.

In the case of the present embodiment of the invention, the adjustment of the directional characteristics of the directional antennas relative to each other in dependence on the rotation angle of the rotatable member 4 relative to the stationary part 3 , The rotation angle is in the case of the present embodiment of the invention with at least one angle encoder 32 determined. The respective current rotation angle are both the receiver 20 as well as the broadcasters 24 . 25 , in particular their antenna electronics 22 . 27 and 30 for setting or tracking the directional characteristic available.

Does the transmitter move? 24 in the 2 Exemplary registered angle range of 270 ° and 90 ° in the direction of rotation R are the directional characteristic of the directional antenna 21 Recipient 20 illustrated by the fan of rays 23 from the antenna electronics 22 and the directional characteristic of the directional antenna 26 the transmitter 24 illustrated by the fan of rays 28 from the antenna electronics 27 in each case depending on the respective current rotation angle always aligned, so that a data transmission from the rotatable part 4 on the stationary part 3 he follows. As mentioned, the data transmission preferably takes place outside the measuring field 12 ,

The 2 to 4 show exemplarily three different positions of the rotatable part 4 and the stationary part 3 or the recipient 20 and the transmitter 24 and 25 relative to each other, wherein the directional characteristics of the directional antennas 21 and 26 respectively. 29 are aligned according to each other.

As long as the transmitter 24 in the angular range between 270 ° and 90 ° or the transmitter 25 moving in the angular range between 90 ° and 270 °, the transmitter is 25 inactive, as a data transfer between the transmitter 25 to the recipient 20 by radio is not possible without radio waves through the measuring field 12 be sent, which is not desirable.

Reached the transmitter 25 however, the 270 ° position and the transmitter 24 the 90 ° position, as in 4 is shown, based on the current rotation angle, the transmitter 25 active and the transmitter 24 inactive, the receiver being 20 at this moment of the 90 ° position associated directional characteristic must revert to the directional characteristic associated with the 270 ° position. Subsequently, as long as the transmitter 25 in the angular range of 270 ° to 90 ° moves, the directional characteristic of the directional antenna 21 Recipient 20 illustrated by the fan of rays 23 from the antenna electronics 22 and the directional characteristic of the directional antenna 29 the transmitter 25 illustrated by the fan of rays 31 from the antenna electronics 30 in each case depending on the respective current rotation angle always again aligned with each other that a data transfer from the rotatable part 4 on the stationary part 3 he follows.

As long as the transmitter 25 in the angular range between 270 ° and 90 ° or the transmitter 24 moving in the angular range between 90 ° and 270 °, the transmitter is 24 inactive.

In this way, by means of an adjustable or tracked radio link, data, in particular measurement data from the rotatable part 4 on the stationary part 3 be transmitted.

In variation to that on the basis of 2 to 4 illustrated embodiment of the invention can also only a directional antenna having transmitter on the rotatable part 4 and two each having a directional antenna receiver, preferably 180 ° opposite each other on the stationary part 3 are arranged, wherein the directional characteristics of the directional antennas are aligned in a corresponding manner, for example, depending on the respective current rotation angle to each other, so that a data transmission from the rotatable part 4 on the stationary part 3 can be done.

Similarly, a data transfer from the stationary part can be 3 on the rotatable part 4 realize. In this case, one or two transmitters each having a directional antenna are arranged on the stationary part and one or two receivers each having a directional antenna are arranged on the rotatable part.

In the case of the described embodiment of the invention and its variation, both the transmitter (s) and the receiver or receivers have directional antennas. But it would also be sufficient to run only the antennas of the transmitter or only the antennas of the receiver as directional antennas. The antenna or antenna, which is not designed as a directional antenna, can have a large acceptance angle, for example a spherical antenna characteristic with an acceptance angle of 360 °. In this case, the antennas of the transmitter or transmitters are preferably designed as directional antennas.

In the 5 and 6 a further embodiment of the invention is shown, which is a data transmission from the rotatable part 4 on the stationary part 3 concerns. In this embodiment of the invention are on the stationary part 4 180 ° opposite each other two receivers 40 . 41 firmly arranged. The recipient 40 has a directional antenna in the form of a phased array antenna 42 with assigned antenna electronics 43 on. The fan of rays 44 illustrates the directional characteristic of the directional antenna 42 that with the antenna electronics 43 dynamically electronically adjustable. The recipient 41 has a directional antenna 45 in the form of a phased array antenna with associated antenna electronics 46 on. The fan of rays 47 illustrates the directional characteristic of the directional antenna 45 that with the antenna electronics 46 is also dynamically adjustable electronically.

At the rotatable part 4 are 180 ° opposite each other two transmitters 50 . 51 firmly arranged. The transmitter 50 has a directional antenna in the form of a phased array antenna 52 with assigned antenna electronics 53 on. The fan of rays 54 illustrates the directional characteristic of the directional antenna 52 that with the antenna electronics 53 dynamically electronically adjustable. The transmitter 51 has a directional antenna in the form of a phased array antenna 55 with assigned antenna electronics 56 on. The fan of rays 57 illustrates the directional characteristic of the directional antenna 55 that with the antenna electronics 56 in turn is dynamically adjustable electronically.

During operation of the X-ray computer tomography device 1 stand after this embodiment of the invention is always two tracking radio links for data transmission from the rotating part 4 on the stationary part 3 to disposal. Does the transmitter move? 50 in the angular range between 270 ° and 90 ° it forms with the receiver 40 a directional radio link, wherein the directional characteristics of the directional antennas 42 and 52 depending on the respective rotation angle, the rotating part 4 with the stationary part 3 each includes, from the antenna electronics 43 and 53 be electronically adjusted or tracked so that the directional characteristics are aligned with each other and outside the measuring field 12 lie.

How out 6 shows, the transmitter moves 51 at the same time in the angular range between 90 ° and 270 °, so that the transmitter 51 with the receiver 41 forms a further radio link, wherein the directional characteristics of the directional antennas 45 and 55 depending on the respective rotation angle, the rotating part 4 with the stationary part 3 each includes, from the antenna electronics 46 and 56 be electronically adjusted or tracked so that the directional characteristics are aligned with each other and outside the measuring field 12 lie.

Finally, the transmitter moves 50 in the angular range between 90 ° and 270 ° it forms with the receiver 41 a radio link. At the same time the transmitter forms 51 if it moves in the angular range between 270 ° and 90 °, a radio link with the receiver 40 , When the 90 ° position or 270 ° position is exceeded by the transmitters 50 . 51 in each case a switching of the receiver 40 . 41 on each located in their transmission area transmitter.

In this way, two radio links can be realized simultaneously, so that the double transmission capacity of data is available. Increasing the number of transmitters and receivers, one can also increase the number of simultaneously available radio links and thus the transmission capacity of data or multiply. Apart from the tracking of the directional characteristics of the directional antennas, depending on the rotation angle always corresponding pairs of transmitter and receiver are to be formed.

Also for the basis of the 5 and 6 described embodiment, that it would be sufficient only the antennas of the transmitter or only the antennas of the receiver to perform as directional antennas.

In the 5 and 6 is a data transfer from the rotatable part 4 on the stationary part 3 shown. In a corresponding manner, however, data transmission from the stationary part to the rotatable part can also be realized if the two transmitters on the stationary part and the two receivers on the rotatable part are arranged correspondingly.

The setting or tracking of the directional characteristics of the directional antennas can also be done depending on the quality of the transmission factor between two directional antennas, moreover. The directions of the directional characteristics, per revolution of the rotatable part 4 around the measuring field 12 can always be adjusted or tracked in the same way, can be adjusted or tracked in this case in their speed and direction that a predetermined threshold for the transmission factor is not exceeded.

In the case of the embodiments of the invention described above, the rotatable part 4 arranged transmitter incidentally in a manner not shown directly to the X-ray detector 7 or a not explicitly shown electronic unit of the rotatable part 4 connected to the X-ray detector 7 derived measuring data to the respective transmitter for data transmission.

Furthermore, those at the stationary part 3 arranged receiver with the image computer 13 for further data processing, that of the X-ray detector 7 associated with measured data.

Both on the rotatable part 4 as well as on the stationary part 3 For example, one or more control units can be present which correspondingly control the antenna electronics of the transmitters and receivers for setting the directional characteristics of the directional antenna assigned to them. However, the antenna electronics can themselves also be designed so that they adjust the directional characteristics, for example, depending on the rotation angle provided.

As explained above, with the invention, data transmission from the stationary to the rotatable part of the gantry and from the rotatable to the stationary part of the gantry can be realized. However, it is not necessary to carry out both the data transmission from the stationary to the rotatable part of the gantry and the data transmission from the rotatable to the stationary part of the gantry in the form of an adjustable or trackable radio link. For example, the data transmission from the stationary to the rotatable part by means of slip rings, capacitive or optical and the data transmission from the rotatable to the stationary part of the gantry with an adjustable or trackable radio link can be made.

The use of pure adjustable or trackable radio links for data transmission has the advantage that it can be dispensed with expensive transmission techniques, such as slip rings and the capacitive transmission of data. In addition, the space required for the radio links components, such as data transmitter and receiver, is less than, for example, slip rings. Furthermore, with adjustable or trackable radio links, the transmission capacity can be increased and the use of multiple radio bands is open.

Claims (26)

Computed tomography device ( 1 ) with a gantry ( 2 ), comprising a stationary part ( 3 ) and a rotatable part ( 4 ), which rotatable part ( 4 ) in the operation of the computed tomography device ( 1 ) around a disk-shaped or cylindrical measuring field ( 12 ), in which a measuring object (P) can be arranged, rotates in which, for a data transmission from the rotatable part (FIG. 4 ) to the stationary part ( 3 ) and / or for a data transmission from the stationary part ( 3 ) to the rotatable part ( 4 ) at the stationary part ( 3 ) or on the rotatable part ( 4 ) at least a first, a directional characteristic directional antenna ( 26 . 29 . 52 . 55 ) whose directional characteristic for suppressing a multipath reception within the gantry in the direction of at least one second, with the directional antenna ( 26 . 29 . 52 . 55 ) cooperating, on the rotatable part ( 4 ) or at the stationary part ( 3 ) arranged antenna ( 21 . 42 . 45 ) is electronically adjustable, wherein the directional characteristic of the at least one first directional antenna ( 26 . 29 . 52 . 55 ) is set electronically such that the data transmission between the at least one first directional antenna ( 26 . 29 . 52 . 55 ) and the at least one second antenna ( 21 . 42 . 45 ) outside the measuring field ( 12 ) he follows. Computed tomography device according to Claim 1, in which the electronic adjustment of the directional characteristic of the at least one first directional antenna ( 26 . 29 . 52 . 55 ) in the direction of the at least one second antenna ( 21 . 42 . 45 ) as a function of the angle of rotation of the rotatable part ( 4 ) relative to the stationary part ( 3 ) he follows. Computed tomography device according to one of Claims 1 or 2, in which the electronic adjustment of the directional characteristic of the at least one first directional antenna ( 26 . 29 . 52 . 55 ) in the direction of the at least one second antenna ( 21 . 42 . 45 ) depending on the quality of the transmission factor between the at least one first directional antenna ( 26 . 29 . 52 . 55 ) and the at least one second antenna ( 21 . 42 . 45 ) he follows. Computed tomography device according to one of claims 1 to 3, wherein the at least one second antenna ( 21 . 42 . 45 ) an electronically adjustable directional pattern directional antenna ( 21 . 42 . 45 ). Computed tomography device according to claim 4, in which the electronic adjustment of the directional characteristics of the at least one first directional antenna ( 26 . 29 . 52 . 55 ) and the at least one second directional antenna ( 21 . 42 . 45 ) relative to one another depending on the angle of rotation of the rotatable part ( 4 ) relative to the stationary part ( 3 ) he follows. Computed tomography device according to Claim 4 or 5, in which the electronic adjustment of the directional characteristics of the at least one first directional antenna ( 26 . 29 . 52 . 55 ) and the at least one second directional antenna ( 21 . 42 . 45 ) relative to each other depending on the quality of the transmission factor between the at least one first directional antenna ( 26 . 29 . 52 . 55 ) and the at least one second directional antenna ( 21 . 42 . 45 ) he follows. Computed tomography device according to one of Claims 1 to 6, in which on the rotatable part ( 4 ) two data transmitters ( 24 . 25 ), each of which has a directional antenna ( 26 . 29 ) are arranged opposite one another and in which at the stationary part ( 3 ) a data receiver ( 20 ) is arranged, the at least one second antenna ( 21 ) having. Computed tomography device according to Claim 7, in which the directional characteristics of the directional antennas ( 26 . 29 ) of the two on the rotatable part ( 4 ) arranged data transmitter ( 24 . 25 ) during the rotation of the rotatable part ( 4 ) around the measuring field ( 12 ) are set electronically such that always a data transmission between at least one of the two directional antennas ( 26 . 29 ) and the at least one second antenna ( 21 ) of the stationary part ( 3 ) data receiver ( 20 ). Computed tomography device according to one of Claims 1 to 6, in which on the rotatable part ( 4 ) a data transmitter is arranged, which has a directional antenna, and in which at the stationary part ( 3 ) two data receivers are arranged opposite each other, each having a second antenna. Computed tomography device according to Claim 9, in which the directional characteristic of the directional antenna of the rotatable part ( 4 ) arranged during the rotation of the rotatable member ( 4 ) around the measuring field ( 12 ) is set so electronically that always a data transmission between the directional antenna and at least one of the second antennas of the stationary part ( 3 ) arranged data receiver can be done. Computed tomography device according to one of Claims 1 to 6, in which on the rotatable part ( 4 ) or at the stationary part ( 3 ) at least two data transmitters ( 50 . 51 ), each of which has a directional antenna ( 52 . 55 ) are arranged opposite one another and in which at the stationary part ( 3 ) or on the rotatable part ( 4 ) at least two data receivers ( 40 . 41 ), each of which has a second antenna ( 42 . 45 ), are arranged opposite one another. Computer tomography apparatus according to claim 11, in which the directional characteristics of the directional antennas ( 52 . 55 ) of the at least two data transmitters ( 50 . 51 ) during the rotation of the rotatable part ( 4 ) around the measuring field ( 12 ) are set electronically such that always a data transmission between at least one of the at least two directional antennas ( 52 . 55 ) the data transmitter ( 50 . 51 ) and at least one of the at least two second antennas ( 42 . 45 ) the data receiver ( 40 . 41 ). Computed tomography device according to one of Claims 1 to 12, in which the directional antenna is in the form of a phased array antenna ( 21 . 26 . 29 . 42 . 45 . 52 . 55 ) is trained. Method for data transmission in a computed tomography device ( 1 ), which is a gantry ( 2 ) with a stationary part ( 3 ) and with a rotatable part ( 4 ), which rotatable part ( 4 ) in the operation of the computed tomography device ( 1 ) around a disk-shaped or cylindrical measuring field ( 12 ), in which a measuring object (P) can be arranged, is rotated, in which for data transmission from the rotatable part ( 4 ) to the stationary part ( 3 ) and/ or for data transmission from the stationary part ( 3 ) to the rotatable part ( 4 ) at the stationary part ( 3 ) or on the rotatable part ( 4 ) at least one first directional antenna having a directional characteristic ( 26 . 29 . 52 . 55 ) whose directional characteristic for suppressing a multipath reception within the gantry in the direction of at least one second, with the directional antenna ( 26 . 29 . 52 . 55 ) cooperating, on the rotatable part ( 4 ) or at the stationary part ( 3 ) arranged antenna ( 21 . 42 . 45 ) is set electronically, wherein the directional characteristic of the at least one first directional antenna ( 26 . 29 . 52 . 55 ) is set electronically such that the data transmission between the at least one first directional antenna ( 26 . 29 . 52 . 55 ) and the at least one second antenna ( 21 . 42 . 45 ) outside the measuring field ( 12 ) he follows. Method according to Claim 14, in which the electronic adjustment of the directional characteristic of the at least one first directional antenna ( 26 . 29 . 52 . 55 ) in the direction of the at least one second antenna ( 21 . 42 . 45 ) as a function of the angle of rotation of the rotatable part ( 4 ) relative to the stationary part ( 3 ) he follows. Method according to one of Claims 14 or 15, in which the electronic adjustment of the directional characteristic of the at least one first directional antenna ( 26 . 29 . 52 . 55 ) in the direction of the at least one second antenna ( 21 . 42 . 45 ) depending on the quality of the transmission factor between the at least one first directional antenna ( 26 . 29 . 52 . 55 ) and the at least one second antenna ( 21 . 42 . 45 ) he follows. Method according to one of Claims 14 to 16, in which the at least one second antenna has a directional antenna which has an electronically adjustable directional characteristic ( 21 . 42 . 45 ). A method according to claim 17, wherein the electronic adjustment of the directional characteristics of the at least one first directional antenna ( 26 . 29 . 52 . 55 ) and the at least one second directional antenna ( 21 . 42 . 45 ) relative to one another depending on the angle of rotation of the rotatable part ( 4 ) relative to the stationary part ( 3 ) he follows. Method according to Claim 17 or 18, in which the electronic adjustment of the directional characteristics of the at least one first directional antenna ( 26 . 29 . 52 . 55 ) and the at least one second directional antenna ( 21 . 42 . 45 ) relative to each other depending on the quality of the transmission factor between the at least one first directional antenna ( 26 . 29 . 52 . 55 ) and the at least one second directional antenna ( 21 . 42 . 45 ) he follows. Method according to one of claims 14 to 19, wherein on the rotatable part ( 4 ) two data transmitters ( 24 . 25 ), each of which has a directional antenna ( 26 . 29 ) are arranged opposite one another and in which at the stationary part ( 3 ) a data receiver ( 20 ) is arranged, the at least one second antenna ( 21 ) having. Method according to Claim 20, in which the directional characteristics of the directional antennas ( 26 . 29 ) of the two on the rotatable part ( 4 ) arranged data transmitter ( 24 . 25 ) during the rotation of the rotatable part ( 4 ) around the measuring field ( 12 ) are set electronically such that always a data transmission between at least one of the two directional antennas ( 26 . 29 ) and the at least one second antenna ( 21 ) of the stationary part ( 3 ) data receiver ( 20 ) he follows. Method according to one of claims 14 to 19, wherein on the rotatable part ( 4 ) a data transmitter is arranged, which has a directional antenna, and in which at the stationary part ( 3 ) two data receivers are arranged opposite each other, each having a second antenna. Method according to Claim 22, in which the directional characteristic of the directional antenna of the rotatable part ( 4 ) arranged during the rotation of the rotatable member ( 4 ) around the measuring field ( 12 ) is set so electronically that always a data transmission between the directional antenna and at least one of the second antennas of the stationary part ( 3 ) arranged data receiver takes place. Method according to one of claims 14 to 19, wherein on the rotatable part ( 4 ) or at the stationary part ( 3 ) at least two data transmitters ( 50 . 51 ), each of which has a directional antenna ( 52 . 55 ) are arranged opposite one another and in which at the stationary part ( 3 ) or on the rotatable part ( 4 ) at least two data receivers ( 40 . 41 ), each of which has a second antenna ( 42 . 45 ), are arranged opposite one another. Method according to Claim 24, in which the directional characteristic of the directional antennas ( 52 . 55 ) of the at least two data transmitters ( 50 . 51 ) during the rotation of the rotatable part ( 4 ) around the measuring field ( 12 ) are set electronically such that always a data transmission between at least one of the at least two directional antennas ( 52 . 55 ) the data transmitter ( 50 . 51 ) and at least one of the at least two second antennas ( 42 . 45 ) the data receiver ( 40 . 41 ) he follows. Method according to one of Claims 14 to 25, in which the directional antenna is in the form of a phased array antenna ( 21 . 26 . 29 . 42 . 45 . 52 . 55 ) is trained.

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