DE102020128451B3 - Fractal antenna, in particular for a therapy device for treating patients, a belt and a therapy device for treating patients with the aid of such a fractal antenna - Google Patents

Abstract

Fractal antenna (10), in particular for a therapy device for treating patients (60), comprising: a carrier substrate (20), an electrical conductor (12), a first connection contact (13a) and a second connection contact (13b). The conductor (12) forms a first fractal geometry (14) and two second fractal geometries (16), which are a self-image of the first fractal geometry (14). The fractal geometries (14, 16) each have a first circular arrangement (115a, 215a) and a second, smaller circular arrangement (115b, 215b). A first circular path (100-01) runs between the first arrangement (115a) and the second arrangement (115b) of the first fractal geometry (14). The circular arrangements (215a, 215b) of the second fractal geometry (16) are arranged on the first circular path (200-01).

Description

The invention relates to a fractal antenna, in particular for a therapy device for treating patients, a belt that can be put on a patient, and a therapy device for treating a patient.

Fractal antennas are known from the prior art which enable energy from electromagnetic radiation to be converted into electrical energy. For example, describes DE 10 2014 223 437 A1 a device that carries out such a conversion with the aid of a fractal antenna integrated into a large-area, macroscopic tissue. For this purpose, the fractal antenna described has a conductive structure and is an integral part of a tissue structure. The fabric consists of straight weft threads and warp threads that are threaded into these weft threads.

Also disclosed DE 10 2011 007 058 A1 an alternative embodiment of an electrical conductor track which has an arcuate modification of a shape of at least a part of a fractal of the second iteration. The part of the fractal is larger than twice a first iteration of the fractal. The curved shape, for changes in direction, has a curve radius that is larger than a predefined minimum curve radius. The arcuate modification of the corners of the fractal reduces reflections and losses in the electrical conductor path when used with HF signals.

It is also off JP 2005 - 303 348 A a fractal antenna is known which has circular arrangements. This fractal antenna is particularly suitable for use as a broadband antenna used for UWB (Ultra Wide Band) communication and the like.

The invention is based on the object of providing a fractal antenna with an alternative arrangement to the known solutions, as well as a belt and a therapy device with such a fractal antenna.

The object is achieved by a fractal antenna according to claim 1, a belt according to claim 11 and a therapy device according to claim 13. Advantageous configurations are the subject of the dependent claims.

The fractal antenna can in particular be integrated in a therapy device for treating patients, in particular humans or animals, such as dogs or horses. The fractal antenna comprises a carrier substrate which has a front side and a rear side facing away from the front side. An electrical conductor for carrying electrical energy is arranged at least partially on the front side of the carrier substrate. The conductor has a first end portion and a second end portion. At least one first connection contact is connected to the first end section of the conductor. At least one second connection contact is connected to the second end section of the conductor. The conductor forms at least a first fractal geometry and at least two second fractal geometries, which are essentially a self-mapping of the first fractal geometry.

The fractal antenna according to the invention is characterized in that the first fractal geometry and the second fractal geometry each have at least a first essentially circular arrangement and a second essentially circular arrangement. The first substantially circular configuration has a first center point and a first radius, and the second substantially circular configuration has a second center point and a second radius that is smaller than the first radius. A first circular path, which has a circular path center, runs between the first arrangement and the second arrangement of the first fractal geometry. The first center point and the second center point of the circular arrangement of the first fractal geometry and the center point of the circular path coincide. The first center point and the second center point of the circular arrangement of the second fractal geometry are arranged on the first circular path.

The fractal antenna described can be used in the treatment of patients. For this purpose, the fractal antenna is positioned in the vicinity of the patient, for example. Existing electromagnetic rays can thus be detected and diverted by the fractal antenna. Energy in the form of electromagnetic radiation is, so to speak, absorbed by the fractal antenna and converted into electrical energy.

The carrier substrate can be any means that is suitable for positioning the defined arrangement of the conductor. For example, the carrier substrate could be a fabric, leather, wood, plastic or a circuit board, and the conductor could be a wire made of copper or another conductive metal or a conductor track on a circuit board. The connection contact can, for example, be a soldering eye on which, for example, an electrically conductive connection can be made with a cable or a connection provided for this purpose.

A self-image is to be understood as an image that depicts itself. A self-mapping of a first iteration is, for example, the second fractal geometry, which shows the first fractal geometry reduced. A mapping of the second iteration would be a third fractal geometry, for example, which shows the second fractal geometry on a reduced scale. The formation of a third fractal geometry by the conductor is a preferred embodiment of the fractal antenna according to the invention. Furthermore, it would be conceivable to provide a large number of iterations. A second or third iteration is currently possible for manufacturing reasons. The number of iterations depends on the space available and the carrier substrate and conductor used. However, as the development of possible carrier substrates and conductors progresses, further iterations may become possible.

The fractal antenna according to the invention is also distinguished by a first, essentially circular arrangement and a second, essentially circular arrangement. It would also be conceivable to provide a third, a fourth or a plurality of essentially circular arrangements, each of which has a radius which becomes smaller as the arrangement progresses. The radius of the arrangements of a fractal geometry is reduced in an advantageous manner in constant steps, for example by a constant value or by a constant ratio, such as 1 to 2, of the radii.

More preferably, the first radius of the first fractal geometry is related to the first radius of the second fractal geometry. The ratio is between 1: 2 and 1: 16, preferably 1: 8. The ratio described can also be used for all further radii, a fractal geometry of one iteration with a fractal geometry of the next iteration.

“Essentially circular arrangement” is to be understood as meaning that it can also be an oval or polygonal arrangement, insofar as the intended radius is included in a section of the arrangement. Furthermore, “essentially circular arrangement” in the sense of a fractal geometry is to be understood as a non-closed circle. Because of the circular arrangements, it is easier to manufacture using, for example, printed circuit boards as the carrier substrate.

The imaginary circular path running between the first and the second arrangement is preferably positioned centrally between two arrangements. The at least two fractal geometries arranged on the circular path are self-images of the first iteration. The center of these self-images is preferably located on the circular path. In a further advantageous embodiment, eight fractal geometries of the first iteration can be arranged on a circular path. It would also be conceivable here to arrange more or less fractal geometries of the same iteration on a circular path. Furthermore, between the possibly existing third and fourth arrangements, there can also be corresponding circular paths with eight fractal geometries of the first iteration. A fractal geometry of the first iteration is also preferably provided on the center point.

In a preferred embodiment, a multiplicity of fractal geometries of an iteration is provided. Preferably four to twelve, more preferably six to ten and most preferably eight fractal geometries are arranged on the respective circular path, the fractal geometries advantageously being distributed equidistantly from one another on the circular path. The shape of the fractal antenna resulting from the guidance of the conductor through the fractal geometries is thus essentially spiral-shaped.

In an advantageous embodiment of the fractal antenna, it is characterized by a first fractal antenna and a second fractal antenna corresponding to the previously described fractal antenna, which are arranged on the carrier substrate. The first fractal antenna and the second fractal antenna are preferably not directly connected to one another.

In a further preferred embodiment, the carrier substrate is a double-sided printed circuit board and / or the conductor is a conductor track. The double-sided circuit board can consist of a carrier material that is copper-clad at the top and bottom. The conductor tracks can be etched from these two copper layers. Such double-sided circuit boards are also called 2-layer circuit boards, two-layer circuit boards or bilayers. The upper copper layer and the lower copper layer can be connected to one another by means of a bore, whereby an electrical connection between the two layers can be established.

By means of such a double-sided printed circuit board, for example, the ends of several fractal geometries can preferably be connected to one another via the rear side. This is advantageous because, in a simple solution, contact of the conductor track at the crossover points of the conductor is prevented.

The circuit board is preferably arranged in a housing. The fractal antenna can be protected accordingly.

To position the circuit board in the housing, the circuit board can have one recess or several recesses. That The housing accordingly has one or more connecting webs which protrude through the recess in the circuit board.

For simple attachment of the housing to, for example, a therapy device, the housing advantageously has a connecting means, in particular a push button and / or a Velcro fastener. A fast and simple attachment can be made possible by means of such a connecting means. In one possible embodiment, the connecting means can be electrically conductive, so that an electrically conductive connection can be made possible. So that the electromagnetic radiation is less shielded by the housing, slots are provided in an advantageous embodiment which allow the fractal antenna to be irradiated in part directly and thus ensure a comparatively high reception strength of the fractal antenna.

In a further embodiment according to the invention, a belt is provided that can be placed on a patient, for example. At least one fractal antenna, as described above, is detachably attached to the belt by, for example, providing the housing of the fractal antenna with a connecting means, such as the aforementioned push button, which is attached to the belt with a counterpart attached there. In a preferred embodiment, the belt can be a belt that is worn around the waist of a patient. It would also be conceivable for the belt to be placed around another part of the patient's body. Furthermore, conductor cables are integrated in the belt, which have a connection to the electrically conductive connecting means.

In a further possible embodiment, the belt can also have a large number of fractal antennas. The fractal antennas are preferably arranged equidistantly along the belt. In this case, the belt can at the same time represent the carrier substrate in an advantageous manner.

In a further embodiment according to the invention, a therapy device for treating a patient is provided. The therapy device has a fractal antenna corresponding to the embodiment described above or a belt corresponding to the embodiment described above.

In an advantageous embodiment, the fractal antenna of the therapy device is grounded, as a result of which a charge of the fractal antenna can be discharged. In a preferred embodiment of this, the first and / or the second connection contact are connected to ground.

Furthermore, in a further advantageous embodiment, the therapy device has a control device. The control device is advantageously designed to switch between a connection to ground and the first connection contact or the second connection contact. Accordingly, the control device can control whether the fractal antenna is discharged via the first connection contact or the second connection contact. Figuratively speaking, a discharge can take place clockwise, i.e. clockwise, and once counterclockwise, i.e. counterclockwise.

Furthermore, in a further advantageous embodiment, the control device is designed to interconnect the first fractal antenna and the second fractal antenna via the control device. In an advantageous embodiment of this, the first fractal antenna and the second fractal antenna can thus be connected in series or in parallel. Depending on the interconnection, it is thus possible, for example, to switch in different combinations when two fractal antennas are present on a carrier substrate, each of which is connected to the control device via the connection contacts. It is thus possible to discharge both fractal antennas “left-handed” or “right-handed”. A combination of these is also possible, namely in that one fractal antenna is discharged “counterclockwise” and the other fractal antenna “clockwise”.

• 1 eine erfindungsgemäße Therapievorrichtung;
• 2a eine vereinfachte Darstellung der Fraktalantenne;
• 2b eine vereinfachte Darstellung der fraktalen Geometrie;
• 3 eine Fraktalantenne in einem zweiten Ausführungsbeispielen;
• 4 eine Vorderansicht auf die Fraktalantenne des zweiten Ausführungsbeispiels;
• 5 eine Rückansicht auf die Fraktalantenne des zweiten Ausführungsbeispiels;
• 6 eine Vorderansicht auf den erfindungsgemäßen Gurt;
• 7 eine Vorderansicht auf den Gurt;
• 8a eine Vorderansicht auf das Gehäuse;
• 8b eine Rückansicht auf das Gehäuse und
• 8c eine Seitenansicht auf das Gehäuse.

The invention is described below using possible exemplary embodiments in conjunction with the schematic drawings. It shows:

• 1 a therapy device according to the invention;
• 2a a simplified representation of the fractal antenna;
• 2 B a simplified representation of the fractal geometry;
• 3 a fractal antenna in a second embodiment;
• 4th a front view of the fractal antenna of the second embodiment;
• 5 a rear view of the fractal antenna of the second embodiment;
• 6th a front view of the belt according to the invention;
• 7th a front view of the belt;
• 8a a front view of the housing;
• 8b a rear view of the housing and
• 8c a side view of the housing.

1 shows a therapy device 50 to treat a patient 60 . The therapy device 50 includes a strap 40 and one on it in a case 30th arranged fractal antenna 10 which via conductor cable 41 with a control unit 52 connected is.

The belt 40 is comparable to a belt around the patient's waist 60 . In 6th and 7th is the strap 40 shown in more detail. On the strap 40 are a total of six fractal antennas 10 which in one housing 30th are positioned, arranged. These fractal antennas 10 are evenly distributed and with a constant distance to each other, so to speak equidistant, on the belt 40 positioned. On the strap 40 are lanyards 32 arranged together with a conductor cable 41 an electrically conductive connection with the control unit 52 can enable. The one on the strap 40 existing lanyards 32 form the counterpart of the one on the housing 30th existing lanyards 32 . The belt 40 furthermore has a locking unit at the ends 42 such as a Velcro fastener.

The case 30th is detailed in 8a until 8c shown. The case 30th encloses the on a carrier substrate 20th Fractal antenna arranged in the form of a printed circuit board 10 . For this purpose, the housing 30th a housing top 30a and a case bottom 30b on which via connecting webs 31 are connected to each other. The connecting webs, not shown 31 are arranged in a columnar manner within the housing. The top of the case 30a also has several slots 34 on which a partially direct irradiation of the fractal antenna 10 allow and, among other things, to cool the fractal antenna 10 to serve. Furthermore, the underside of the housing 30b a lanyard 32 on. The lanyard 32 enables an easily attachable and detachable connection to the belt 30th in the form of a press stud or a Velcro fastener. The connecting means is expedient 32 further designed to enable an electrically conductive connection so that the fractal antenna 10 detected electromagnetic radiation via the belt 30th can be derived.

The fractal antenna according to the invention 10 consists essentially of a continuous conductor 12th who, as in 3 , 4th and 5 shown can be a conductor track. The head 12th is on a carrier substrate 20th arranged, which has a double-sided printed circuit board, as in 4th and 5 shown can be. The carrier substrate 20th includes a front 21 and one of the front 21 averted back 22nd . Furthermore, on a carrier substrate 20th a variety of fractal antennas 10 be arranged. As in 4th and 5 two fractal antennas are shown 10a , 10b arranged on a circuit board.

They are also used to fasten the circuit board in the housing 30th Recesses 26th provided on the circuit board. The connecting bridges 31 of the housing 30th protrude through the recesses 26th . The connecting bridges 31 and the recesses 26th are for this purpose dimensioned in relation to one another so that the circuit board is fixed in a form-fitting manner.

The head 12th has a first end portion 12a and a second end portion 12b on. The end section 12a , 12b each extends over an area of the ladder 12th starting from the respective end. At one point on the first end section 12a is a first connection contact 13a arranged and at a point of the second end portion 12b is a second connection contact 13b arranged. The connection contacts 13a , 13b are each on the front 21 the circuit board 20th . The connection contacts 13a , 13b can be connected to the lanyard via a connector 31 be electrically connected.

This means direct contact at the crossover points of the conductor 12th or the track that is in 3 can be seen, can be avoided, the circuit board has so-called breakthroughs, which the front 21 with the back 22nd connect electrically conductive. By just before a crossing point of the ladder 12th on the back 22nd and after the crossing back to the front 21 is led, becomes the leader 12th bridged. In 4th is the one on the front 21 running conductor track 12th shown and in 5 the corresponding back 22nd the conductor track 12th with the bridging sections required for bridging.

2a shows the course of the conductor in a simplified schematic representation 12th on the front side 21 of the carrier substrate 20th . The head 12th is such on the carrier substrate 20th arranged that the head 12th on the front side 21 a first fractal geometry 14th and two second fractal geometries 16 forms. The second fractal geometries 16 are each a self-image of the first fractal geometry 14th . Corresponding is a third fractal geometry 18th a self-map of the second fractal geometry 16 .

2 B shows the fractal geometries in a schematic representation 14th , 16 , 18th . The reference symbols 100 to 199 relate to features of the first fractal geometry 14th , the reference numerals 200 to 299 relate to features of the second fractal geometry 16 and numerals 300 to 399 relate to features of the third fractal geometry 18th . The features of the second and third fractal geometries 16 , 18th are comparable to the features of the first fractal geometry 14th . In the following, the features of the fractal geometry are correspondingly only based on the first fractal geometry 14th described. However, the configuration of the features apply to the second, third and further iterations of the fractal geometry and are shown in the drawings by means of reference symbols, the reference symbol of the next higher iteration being added with a value of 100. By way of example, the first radius thus has the first fractal geometry 14th the reference number 115a on, the first radius of the second fractal geometry 16 the reference number 215a on and the first radius of the third fractal geometry 18th the reference number 315a on.

In the 2a and 2 B first fractal geometry shown 14th comprises a first substantially circular arrangement 115a having a first focal point 100-MP1 and a first radius 100-r1 Has. The first also includes fractal geometry 14th a second substantially circular arrangement 115b having a second center point 100-MP2 and a second radius 100-r2 Has. In addition, the in 2 B shown first fractal geometry 14th a third substantially circular arrangement 115c having a third focal point 100-MP3 and a third radius 100-r3 Has. Correspondingly, further arrangements can be included, such as on the basis of the fractal antenna 10 the 3 , 4th and 5 you can see. The second radius 100-r2 is half the length of the first radius 100-r1 and the third radius 100-r3 is half the length of the second radius 100-r2 . The radii are therefore in a ratio of 1: 2.

Between the first arrangement 115a and the second arrangement 115b the first fractal geometry 14th a first circular path runs 100-O1 that have a circular orbit center 100-O1-MP Has. Between the second arrangement 115b and the third arrangement 115c a second circular path 100-O2 runs, which has a circular path center point 100-O2-MP. The circular orbits 100-O1 , 100-O2 are each centered between the adjacent arrangements 115a , 115b and 115c positioned and only represent an imaginary auxiliary line for positioning the fractal geometries.

The first center point 100-MP1 , the second center point 100-MP2 and the third center point 100-MP3 of circular arrangements 115a , 115b , 115c the first fractal geometry 14th and the center of the circular path 100-O1-MP , 100-O2-MP collapse, so the arrangements 115a , 115b , 115c are positioned concentrically to one another.

As in 2a is the second fractal geometry 16 such within the first fractal geometry 14th arranged so that the center point 200-MP1 the first arrangement 215a the second fractal geometry 16 on the circular path 100-O1 lies. Correspondingly, on a circular path 100-O1 , 100-O2 eight second fractal geometries 16 be positioned as it is based on the second embodiment according to 3 , 4th and 5 can be seen. The second fractal geometries 16 are in particular evenly distributed on the circular path 100-O1 , 100-O2 positioned. There is also the first radius 200-r1 the second fractal geometries 16 in a ratio of 1: 8 to the first radius 100-r1 the first fractal geometry 14th .

3 , 4th and 5 shows an embodiment with three circular paths 100-O1 , 100-O2, 100-O3 and a second fractal geometry 16 that on the center point 100-O1-MP , 100-O2-MP, 100-O3-MP is arranged. Which is through the guidance of the head 12th through the fractal geometries 14th , 16 , 18th resulting shape of the fractal antenna 10 is thus essentially spiral.

An electrically conductive connection starting from the conductor 12th can via the first connection contact 13a or the second connection contact 13b getting produced. The respective connection contact 13a , 13b is connected to the lanyard via a connecting element 32 electrically connected. The lanyards 32 are with the one in the strap 40 integrated conductor cable 41 tied together. The conductor cable 41 can with the control unit 52 get connected. The control unit 52 again has a connection to ground. The fractal antenna 10 grounded or discharged.

The control unit 52 is also designed via a suitable arrangement of the conductor cables 41 either via the first connection contact 13a or via the second connection contact 13b the fractal antenna 10 to unload.

With a fractal antenna 10 which passes through a first fractal antenna 10a and a second fractal antenna 10b on a carrier substrate 20th the first fractal antenna 10a and the second fractal antenna 10b connected in series or in parallel. Depending on the interconnection, for example, if there are two fractal antennas 10a , 10b on a carrier substrate 20th each with the control unit 52 via the connection contacts 13a , 13b connected, can be switched in various combinations. It would therefore be conceivable that both fractal antennas 10a , 10b can be discharged by turning left or right. Furthermore, a combination of these is also conceivable, namely by using a fractal antenna 10a counterclockwise and the other fractal antenna 10b clockwise is discharged.

List of reference symbols

10

Fractal antenna

10a

first fractal antenna

10b

second fractal antenna

12th

ladder

12a

End section

12b

End section

13a

first connection contact

13b

second connection contact

14th

first fractal geometry

115a

first substantially circular arrangement

100-MP1

first center point

100-r1

first radius

115b

a second substantially circular arrangement

100-MP2

a second center point

100-r2

second radius

100-O1

first circular path

115c

a third substantially circular arrangement

100-MP3

third center

100-r3

third radius100-O1-MP center of the circular path

16

second fractal geometry

215a

first substantially circular arrangement

200-MP1

first center point

200-r1

first radius

215b

a second substantially circular arrangement

200-MP2

a second center point

200-r2

second radius

200-O1

first circular path

200-O1-MP

Circle center point

18th

third fractal geometry

315a

first substantially circular arrangement

300-MP1

first center point

300-r1

first radius

315b

a second substantially circular arrangement

300-MP2

a second center point

300-r2

second radius

300-O1

first circular path

300-O1-MP

Circle center point

20th

Carrier substrate

21

front

22nd

back

26th

Recesses

30th

casing

30a

Housing top

30b

Housing bottom

31

Connecting bridge

32

Lanyard

34

Slots

40

belt

41

Conductor cable

42

Locking unit

50

Therapy device

52

Control unit

60

patient

Claims (18)

Fractal antenna (10), in particular for a therapy device (50) for treating patients (60), comprising: a carrier substrate (20) which has a front side (21) and a rear side (22) facing away from the front side (21); at least one electrical conductor (12) for conducting electrical energy, which is arranged at least partially on the front side (22) of the carrier substrate (20) and has a first end section (12a) and a second end section (12b); at least one first connection contact (13a) which is connected to the first end section (12a) of the conductor (12), and at least one second connection contact (13b) which is connected to the second end section of the conductor (12); wherein the conductor (12) forms at least a first fractal geometry (14) and at least two second fractal geometries (16) which are substantially a self-map of the first fractal geometry (14); characterized in that the first fractal geometry (14) and the second fractal geometry (16) each have at least a first substantially circular arrangement (115a, 215a), which has a first center point (100-MP1, 200-MP1) and a first radius (100-r1, 200-r1), and a second substantially circular arrangement (115b, 215b) having a second center point (100-MP2, 100-MP2) and a second radius (100-r2, 200-r2) smaller than the first radius (100-r1); wherein between the first arrangement (115a) and the second arrangement (115b) of the first fractal geometry (14) a first circular path (100-O1) runs, which has a circular path center (100-O1-MP); wherein the first center point (100-MP1) and the second center point (100-MP2) of the circular arrangements (115a, 115b) of the first fractal geometry (14) and the circular path center point (100-O1-MP) coincide and wherein the first center point ( 200-MP1) and the second center point (200-MP2) of the circular arrangements (215a, 215b) of the second fractal geometry (16) are arranged on the first circular path (200-01). Fractal antenna (10) Claim 1 , characterized in that the second fractal geometry (16) is an iteration of the first fractal geometry (14); wherein the first radius (100-r1) of the first fractal geometry (14) is in a ratio to the first radius (200-r1) of the second fractal geometry (16) and wherein the ratio is between 1 to 2 and 1 to 16, preferably 1 to 8, is. Fractal antenna (10) Claim 1 or 2 , characterized in that the conductor (12) forms a third fractal geometry (18); wherein the third fractal geometry (18) is a self-map of the second fractal geometry (16). Fractal antenna (10) according to one of the Claims 1 until 3 characterized by a plurality of fractal geometries (14, 16, 18) of an iteration; preferably four to twelve, more preferably six to ten, and most preferably eight fractal geometries (14, 16, 18) on the circular path (100-01, 200-01, 300-01; 100-02, 200-02, 300 -O2; 100-03, 200-03, 300-O3) are arranged. Fractal antenna (10) according to one of the Claims 1 until 4th , characterized in that on the carrier substrate (20) a first fractal antenna (10a) and a second fractal antenna (10b) each after one of the Claims 1 until 3 are arranged; wherein the first fractal antenna (10a) and the second fractal antenna (12b) are preferably separated. Fractal antenna (10) according to one of the Claims 1 until 5 , characterized in that the carrier substrate (20) is a double-sided printed circuit board and / or the conductor (12) is a conductor track. Fractal antenna (10) Claim 6 , characterized in that the fractal geometries (14, 16, 18) of a conductor track are connected to one another via the rear side (24) of the circuit board. Fractal antenna (10) Claim 6 or 7th , characterized in that the circuit board (20) is arranged in a housing (30). Fractal antenna (10) Claim 8 , characterized in that the circuit board (20) has at least one recess (26) and the housing (30) has at least one connecting web (31), the connecting web (32) protruding through the recess (26) of the circuit board (20). Fractal antenna (10) Claim 8 or 9 , characterized in that the housing (30) has a connecting means (32), in particular a push button and / or a Velcro fastener. Belt (40) which can be placed on a patient (60), characterized by at least one fractal antenna (10) according to one of the Claims 1 until 10 . Belt (40) Claim 11 , characterized by a plurality of fractal antennas (10), the fractal antennas (10) preferably being arranged equidistantly along the belt (40). Therapy device (50) for treating a patient (60), characterized by a fractal antenna (10) according to one of the Claims 1 until 10 or a belt (40) Claim 11 or 12th . Therapy device (50) after Claim 13 , characterized in that the fractal antenna (10) is grounded; wherein preferably the first connection contact (13a) and / or the second connection contact (13b) is connected to ground. Therapy device (50) after Claim 13 or 14th , characterized by a control device (52). Therapy device (50) after Claim 15 , characterized in that the control device (52) is designed to switch between a connection to ground and the first connection contact (13a) or the second connection contact (13a). Therapy device (50) after Claim 15 or 16 , characterized in that the control device (52) is designed, the first To interconnect the fractal antenna (10a) and the second fractal antenna (10b) via the control unit (52). Therapy device (50) after Claim 17 , characterized in that the first fractal antenna (10a) and the second fractal antenna (10b) can be connected in series or in parallel.

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