WO2009065951A1 - Compact directional antenna arrangement with multiple usage of radiator elements - Google Patents

Abstract

The antenna arrangement (1) according to the invention for receiving and/or transmitting electromagnetic radiation from or in a radiation direction (R) at a mean wavelength λ comprises a first radiator field (12) having N1 first radiator elements (2), a second radiator field (13) having N2 second radiator elements (3), and a high-frequency stage (7), which has a first terminal (8) and a second terminal (9) on the antenna side for providing and/or receiving electrical signals at the mean wavelength λ, said first radiator field (12) being connected to the first terminal (8) and said second radiator field (13) being connected to the second terminal (9), and said first (12) and second (13) radiator fields having substantially identical polarization properties, and said first radiator field (12) and said second radiator field (13) sharing at least one radiator element (4). The transmitting and/or receiving device (10) according to the invention, in particular a mobile station, base station, or radar, having a baseband processing stage (21) and a high-frequency stage (22), comprises the antenna arrangement (1) according to the invention. The invention is characterized by a high degree of compactness, simple producibility, high sensitivity, and directional selectivity.

Description

 COMPACT RANGE ARRANGEMENT WITH MULTIPLE USE OF RADIATION ELEMENTS

The present invention relates to an antenna arrangement for receiving and / or transmitting electromagnetic radiation from or in a radiation direction at a mean wavelength λ.

From DE 102 04 079 a multi-band antenna is known which provides a plurality of active radiators for receiving and / or transmitting electromagnetic radiation at different medium wavelengths.

EP 1 628 140 A1 discloses an interferometric monopulse receiving antenna with improved side lobe suppression, in which a signal emitted by a transmitter antenna is detected by means of at least two substantially identically designed receiving antennas. The distance between the two receive antennas is chosen to reduce ambiguity in an angle measurement based on a phase difference measurement.

Furthermore, DE 10 2006 012 452 discloses a directional antenna arrangement with a photonic bandgap structure (PBG structure), which suppresses a propagation of surface waves within a radiator field having a large number of radiator elements.

DE 10 2005 011 128 discloses an electronically controllable antenna with a plurality of radiator elements, which can be controlled and calibrated in terms of amplitude and / or phase. The electronically controllable antenna comprises a plurality of radiating elements and is in terms of sensitive to different polarization directions.

The production of electronically controllable antennas or directional antenna arrangements with high

Reception sensitivity and directional selectivity are usually associated with significant costs. For a high directional selectivity, a variety of

Emitter elements are housed in a small space.

With increasing wiring, the

Antenna arrangement more complex and more expensive to manufacture.

If the radiator fields of the directional antenna are arranged next to one another, unwanted ambiguities in the determination of the transmission / reception direction increase with increasing distance.

If the radiator fields close to each other or overlapping spaced, an electromagnetic coupling between the closely spaced radiator elements of the different radiator fields can lead to significant distortions of the local electromagnetic field, which affects the impedance behavior of the antenna assembly and an impairment of the sensitivity and the directional selectivity of the antenna assembly with it can lead. A distorted impedance characteristic of the directional antenna arrangement can considerably complicate an electrical control of the plurality of radiator elements which takes this into consideration.

It is therefore an object of the present invention to provide an antenna arrangement for receiving and / or transmitting electromagnetic radiation from or in a radiation direction at a central wavelength λ, which is particularly compact and inexpensive to produce, has high sensitivity and a high degree of directional selectivity having. Furthermore, it is an object to provide a transmitting and / or receiving device which can receive or transmit electromagnetic signals from or in one direction, has a high sensitivity and has a high degree of directional selectivity.

These objects are achieved by the antenna arrangement according to the invention and the transmitting and / or receiving device according to the invention as specified in the independent claims. Further advantageous embodiments and developments, which can be applied individually or combined in any suitable manner, are given in the following description and in the dependent claims.

The antenna arrangement according to the invention for receiving and / or transmitting electromagnetic radiation from or in a radiation direction at a central wavelength λ comprises a first radiator field with Nl first radiator elements, a second radiator field with N2 second radiator elements and a high-frequency stage which is used to provide or receive electrical signals at the central wavelength λ antenna side has a first terminal and a second terminal, wherein the first radiator array is connected to the first terminal and the second radiator array is connected to the second terminal, wherein the first and second radiator array have substantially the same polarization properties, and wherein the first radiator field and the second radiator field have at least one radiator element in common.

The high-frequency stage is particularly suitable for frequencies f in the range of 300 MHz to 200 GHz, preferably in a range of 1 GHz to 80 GHz preferably in a range of 2 GHz and 20 GHz. Corresponding mean wavelengths λ are given by K = c / f, where c is the speed of light. For example, 300 MHz corresponds to a mean wavelength of 1 m and 200 GHz corresponds to 1.5 mm.

An emitter array comprises a plurality of emitter elements, which may be configured, for example, as simple dipole emitters or as patch emitters. The number N 1 of the first radiator elements or the number N 2 of the second radiator elements may be at least 9, in particular at least 25, preferably at least 64, particularly preferably at least 100. The radiator elements within a radiator field can be combined into rows and / or columns. The respective radiator fields can be arranged at a distance above an electrical ground reference surface.

By acting on the radiator fields with a signal at a. Equivalent central wavelength λ can be achieved on the relative phase of the two radiator fields, a directional characteristic and a directional selectivity of the antenna order.

The term "sensitivity" of a directional antenna arrangement is understood to mean its ability to distinguish weak signals from background noise. The term "directional selectivity" of a directional antenna arrangement is used to clearly define or determine a radiation direction of the radiation emitted or received by it.

Through the sharing of radiator elements is an electromagnetic radiation coupling between or under the radiator fields reduced in favor of an electrically conductive connection. In this way, a particularly compact arrangement of multiple radiator panels can be realized. The compactness improves the radiation direction selectivity and reduces ambiguity in direction determination. The radiator elements associated with a radiator field can be connected to one another in an electrically conductive manner within and in the immediate area of the radiator field. By sharing at least a portion of the radiator elements by a plurality of radiator fields, the design of the antenna assembly is considerably simplified and reduces problems with impedance matching and other due to the interaction of the radiator elements impairments of the sensitivity or directional selectivity of the antenna assembly.

Advantageously, more than half of the radiator elements of the radiator panels are shared, preferably more than 80% of the

Radiating elements. It can also all

Radiating elements of the first and / or second

Spotlights are shared. In certain applications, it may be advantageous, not all

Radiator elements of both radiator panels to share but only a part. For example, two are made substantially the same

Radiator fields less than 90% of the radiator elements used jointly by both radiator fields.

The mean wavelength of the electrical signal at the first terminal is substantially the same as that at the second terminal. The signals at the two terminals of the high frequency stage differ depending on the direction of radiation substantially only by their relative phase position. In particular, the high-frequency stage generates or receives at both terminals a signal having substantially the same power spectrum. However, the signals at the two terminals may differ with respect to the relative phase position or with respect to their phase spectra.

The first and the second radiator field have a substantially common polarization direction and can be linearly or circularly polarized.

The at least one radiating element can be part of a plurality of radiator fields by being electrically connected to the respective radiator fields. The electrical connection is made in particular by a (e.g., galvanic) contacting in or in the immediate vicinity of the plane defined by the radiating fields.

In the event that the radiating elements of the respective radiator fields are each fed individually or in subgroups of the high-frequency stage, the common use with respect to the high-frequency stage can also be generated on the band side (in the case of several frequency conversion stages) or on the baseband side (for example in the case of direct frequency conversion). For example, the signals, which correspond in each case to a radiator field, are combined with respect to the high-frequency stage on the baseband side in the transmission mode or separated in the reception mode and jointly assigned to the shared radiator elements or radiator element sub-groups.

The antenna arrangement can be used in particular in a mobile station, a base station or a radar. It can also be related to Feed systems of reflector applications such as used in satellite communication or satellite reception.

In one embodiment, the first terminal defines a first phase center of the first radiator field and the second terminal defines a second phase center of the second radiator field, the two phase centers of the radiator fields being less than a first width of the first radiator field and / or less than a second width of the second radiator field are located apart from each other, in particular less than 400%, preferably less than 100%, particularly preferably less than 70%, the average wavelength λ, are away from each other. The width of a radiator field is defined by the boundary of the radiator field.

A phase center of a radiator field is defined by the middle phase of the radiation field emitted or received by the respective radiator field. The term phase center refers to the electronic reference point of an antenna. From the point of view, the electromagnetic radiation from the point of view seems to originate from this point.

By a smaller spacing of the two phase centers, the uniqueness of the radiation direction is improved.

The distance of the phase centers of the radiator fields is defined as the projection of the phase centers on the pivot plane. The pivot plane is that plane within which the radiation direction can be tilted by changing the relative phase angles of the radiator fields relative to each other.

Advantageously, the first or second Radiator elements arranged in columns and / or rows. By arranging the radiator elements in columns, a pivoting or pivoting of the radiation direction within a plane perpendicular thereto is made possible. Accordingly, by arranging the radiator elements in rows, a pivoting or pivoting of the radiation direction in a correspondingly vertical plane is made possible. In an arrangement of the radiator elements in columns and rows is a pivoting of the radiation direction in the X and Y direction (Z-direction forms the normal to the plane within which the radiator fields are) achieved. The radiation direction can then be controlled, predetermined or influenced both with respect to an elevation angle and with respect to an azimuth angle. A respective subphase center can be assigned to a respective row or column. The subphase centers of the phases or columns assigned to a radiator field contribute to the phase center of this radiator field and form this in their superimposition.

Immediately adjacent radiator elements may form a quadrilateral or a triangle. With an arrangement of the radiator elements based on triangles, a total number of the radiator elements required for a given width of the directional characteristic can be reduced compared to a total number of radiator elements with an arrangement based on quadrilaterals; The disadvantage here, however, may be that in an arrangement based on triangles, the polarization directions can be mixed together.

In a further embodiment, the antenna arrangement comprises one or more further ones

Spotlights with other radiator elements for Receiving and / or transmitting electromagnetic radiation at the central wavelength λ. With the help of additional radiating elements ^■ the antenna array can be expanded by another polarization direction, the radiation direction can be adjusted in a similar manner using the at least two further antenna arrays. In addition, as a result, the direction of radiation along with an X direction in the Y direction (Z direction forms the normal to the plane, which is defined by the radiator fields) can be set and adjusted.

In a further embodiment, the high-frequency stage has suitable first and second further connections. With the help of the high-frequency stage, the relative phase of the radiator fields can be adjusted and thus the radiation direction can be influenced. In particular, the radiation direction R can be influenced by the further radiator fields, both with regard to an azimuth angle and to an elevation angle. With the help of the first, second, ^'the first further and second further connection, the radiation direction and the directional characteristic of the antenna arrangement can be adjusted, in particular can be controlled or realized. The radiation direction or the directional characteristic can advantageously be set with the aid of the radiator fields in more than one plane and / or for more than one polarization direction.

In a further embodiment, the polarization properties of at least one, in particular at least two, of the further radiator fields are different from those of the first and second radiator fields. This causes the radiation direction or radiation characteristic for different Polarization directions can be set independently or specified.

Advantageously, the antenna arrangement comprises one or more Wilkinson splitters for the decoupling of shared radiator elements, rows and / or columns. With the help of the at least one Wilkinson divider, unwanted feedback of the radiator elements, the rows, and / or the columns can be suppressed. Using a Wilkinson divider, high-frequency signals can be split into two or more outputs or two or more high-frequency signals can be combined to form a common output. With a suitable design of the quarter wave lines or the resistivity of the Wilkinson divider, a good decoupling of the respective signals can be achieved.

Advantageously, the antenna arrangement comprises at least one controllable phase shifter for adjusting the relative phase position of the individual radiator elements, the radiator elements combined to form rows or columns and / or the radiator elements combined to radiator fields relative to one another. With the aid of the controllable phase shifter, the radiation direction or the directional characteristic of the antenna arrangement can be adjusted. The phase shifter may be part of the high frequency stage.

In the antenna arrangement, in particular at least one of the following features (Al) to (A4) is fulfilled:

(Al) the first or second radiator field is planar;

(A2) the first or second radiator elements are substantially two-dimensionally planar;

(A3) comprises the first or second radiator field at least 9, in particular at least 25, preferably at least 64, particularly preferably at least 100, radiator elements;

(A4) the first and the second radiator array are designed substantially the same.

Here, a combination of the features (Al), (A2) and (A4) is particularly preferred. The configuration of the feature (A4) facilitates a symmetrical change or adjustment of the radiation direction within the pivot plane from the vertical (Z direction normal to the plane defined by the radiator fields) into positive or negative angle ranges.

In a further development, the first or second radiator elements lie on a grating whose grating spacing is advantageously between 20% and 80% of the central wavelength λ, in particular between 40% and 60% of the central wavelength λ, advantageously between 45% and 55% of the middle Wavelength λ, is. With a reduction of the lattice spacing, the uniqueness of the radiation direction can be improved, and secondary maxima (side lobes) can be further suppressed. In addition to improving the uniqueness of the radiation direction and an improvement in the sensitivity of the antenna array is improved with the same space requirement.

A grid spacing at an edge of the first or second radiator field may be different, in particular greater, than a grid spacing in the interior of the radiator field. By a suitable choice of the lattice spacings, secondary maxima (side lobes) can be reduced or suppressed during the emission or reception.

Advantageously, all the radiator elements lie substantially in one plane. The transmitting and / or receiving device according to the invention, in particular a mobile station, base station or radar, with a baseband processing stage and a high-frequency stage, comprises the antenna arrangement according to the invention. With the aid of the antenna arrangement according to the invention, the transmitting and / or receiving device is given a special sensitivity as well as directional selectivity. The radar can be mobile. The transmitting and / or receiving device can be used in the automotive sector.

Further advantages and particular embodiments will be explained in more detail with reference to the following drawing, which serves merely to illustrate and exemplify the invention. Here are shown schematically:

Fig. 1 shows an antenna arrangement in plan view, as known from the prior art;

2 shows a plan view of a first embodiment of an antenna arrangement according to the invention with a pivoting of the radiation direction in a plane;

Fig. 3 in plan view, a second embodiment of an antenna arrangement according to the invention, which has a pivoting of the

Radiation direction in two levels allows;

4 shows a top view of a further embodiment of an antenna arrangement according to the invention with variable lattice spacings of the radiator elements;

5 shows a transmission and / or reception device according to the invention in cross section; 6 shows in plan view a further embodiment of the antenna arrangement according to the invention with Wilkinson dividers;

Fig. 7 in plan view a further embodiment of an antenna arrangement according to the invention with

Spotlights and more than two feed points.

1 shows a known interferometric monopulse receiving antenna with a first radiator field 12 and a second radiator field 13, wherein the radiator fields 12, 13 are arranged next to one another. The curly brackets illustrated in FIG. 1 represent the respective widths of the radiator panels 12, 13. The radiator panels 12, 13 each have radiator elements 2, 3. Within a radiator field 12, 13, the radiator elements 2, 3 are combined in columns by means of a wiring 24. Since the radiator panels 12, 13 are arranged side by side and thus the distance between the radiating fields 12, 13 associated phase centers is greater than half the average wavelength of the emitted or received radiation, the directional characteristic of the antenna arrangement in phased operation with two transmitters / receivers on secondary maxima which can affect the unambiguous determination of the radiation direction of a received or transmitted signal and can lead to ambiguities in the direction determination. The first radiator field 12 has a first phase center 14. The second radiator field 13 has a second phase center 15.

2 shows an antenna arrangement according to the invention in plan view, in which the first radiator field 12 and the second radiator field 13 overlap. A plurality of radiating elements 4 are of both Emitter fields 12, 13 shared. The first radiator field 12 has a multiplicity of first radiator elements 2, which are combined to form columns 26 by means of a wiring 24. The second radiator field 13 has a plurality of radiator elements 3, which are also combined by means of a wiring 24 to columns 26. The wiring 24 is provided in the immediate vicinity of the radiator elements 2, 3 and within the radiator panels 12,13. The first radiator array 12 has a first feed point 5, which is connected to a first terminal 8 of a high-frequency stage 7 (see FIG. 5). The second radiator field 13 has a second feed point 6, which is connected to a second terminal 9 of the high-frequency stage 7. The phase center 14, 15 of a radiator field 12, 13 is defined by the amplitude weighting of the respective radiator elements 2, 3, rows 16 and columns 2β. The phase centers 14, 15 lie in a plane defined by the gaps 26, ie the planes in which all the radiator elements 2, 3, 4 are located. The distance of the two Phasenzehtren 14, 15 in a direction transverse to the columns 26 is about half an average wavelength λ of the radiated from the antenna assembly 1 electromagnetic radiation. The radiation direction R (see FIG. 5) of the radiation emitted or received by the antenna arrangement 1 can be adjusted variably by means of a suitable choice of the relative phase relationship between the radiator fields 12, 13 in a plane perpendicular to the columns 26. By the common use of radiator elements 4, an electromagnetic radiation coupling between the radiator elements 2, 3 of the radiator panels 12, 13 is reduced and generates an electrical coupling by a galvanic contact. This considerably simplifies the design of the antenna arrangement 1 unwanted interference effects and allows a particularly compact and simple production of the antenna assembly 1. Due to the compactness of the antenna side maxima are suppressed in the directional characteristic of the antenna assembly 1, whereby the sensitivity and directionality of the antenna assembly 1 are increased. The pivoting plane is perpendicular to the columns 26th

(i.e., in Fig. 2 perpendicular to the plane of the drawing from right to left). The radiator elements 2,3 can in one

Distance above an electrical ground reference surface

(not shown) may be arranged.

FIG. 3 shows a further embodiment of the antenna arrangement 1 according to the invention, wherein a directional selectivity, ie a control of the radiation direction, is made possible with the aid of a first further radiator field 12 'and a second further radiator field 13' in two planes. The curly brackets illustrated in FIG. 3 represent the respective widths of the radiator fields 12, 13, 12 'and 13'. The first radiator field 12, the second radiator field 13, the first further radiator field 12 'and the second further radiator field 13' are divided a plurality of radiator elements 4, which thus belong to these radiator fields 12, 12 ', 13, 13' together. The first further radiator field 12 'has a first further feed point 5'. The second further radiator field 13 'has a second further feed point 6'. The first further radiator field 12 'has first further radiator elements 2'. The second further radiator field 13 'has second further radiator elements 3'. With regard to the first radiator field 12, the associated radiator elements 2 are combined into columns 26. Likewise, the radiator elements 3 associated with the second radiator field 13 are combined to form columns 26. The second further radiator array 12 'associated radiator elements 2' are summarized to lines 16. The radiator elements 3 'assigned to the second further radiator field 13' are combined to form lines 16. The respective radiator panels 12, 12 ', 13, 13' are here defined by the wiring 24, the respective feed points 5, 6, 5 ', 6' and the columns 26 and the lines 16. Since the radiator elements 4 belong to a plurality of radiator fields 12, 12 ', 13, 13', ie the radiator fields share radiator elements 4, the shared radiator element 4 forms both a part of a line 26 and a part of a column 16. The first further radiator field 12 'has a first further feed point 5' and the second further radiator field 13 'has a further second feed point 6'. The feed points 5, 5 ', 6, 6' in each case form a phase center in one direction of the respective columns 12, 12 ', 13, 13' associated columns 26 and rows 16. By the arrangement of the radiator elements 2, 3, 2 ' , 3 'is a pivoting of the radiation direction in two planes, namely in the XZ plane and the YZ plane, wherein the Z-direction is defined normal to the plane defined by the radiating elements 2, 2', 3, 3 'level achieved , The horizontal wiring 24 is decoupled from the vertical wiring 24, for example, by one Wilkinson divider (not shown) per radiator element 2, 3, 2 ', 3' (and optionally per polarization direction).

FIG. 4 shows a further embodiment of the antenna arrangement 1 according to the invention in plan view, in which the radiator elements located on an edge 17 lie somewhat further outwards. A lattice constant D 1, D 2, D 3 and D 4 defined by the position of the radiator elements 2, 3 is greater at an edge 17 of the radiator field 12, 13 than in an interior 18. As can be seen in FIG. 4, D1 is greater than D2 and D3 is greater than D4. The ratio between Dl and D2 or between D3 and D4 is between 1.1 and 1.7. In the embodiment according to FIG. 4, all the radiator elements 2, 3 belong to both radiator fields 12, 13. The phase centers 14, 15 of the two radiator fields 12, 13 are defined by the amplitude weighting of the respective radiator elements 2, 3, rows 16 and columns 26 and are less than an average wavelength of the radiated from the Äntennenanordnung 1 radiation away from each other. The radiator elements 2, 3 of the respective radiator panels 12, 13 are interconnected by conductor tracks 19 which lie in the plane defined by the radiator elements 2, 3.

5 shows an embodiment of a transmitting and / or receiving device according to the invention, which comprises an antenna arrangement 1 according to the invention with a high-frequency stage 7 and a baseband processing stage 21. The high-frequency stage 7 comprises a frequency conversion stage 20, a signal splitter or signal combiner 11 and an electronically controllable phase shifter 23.

Baseband processing stage 21,

Frequency conversion stage 20, signal splitter or signal combiner 11 and controllable phase shifter 23 are connected in series. The high-frequency stage 7 is connected to the first terminal 8 and the second terminal 9 to the first 12 and second 13 radiator field, wherein the phase centers 14, 15 of the two radiator panels 12, 13 by the amplitude weighting of the respective radiator elements 2, 3, lines 16 and Columns 26 are defined. The radiation direction R can be determined by means of the relative phase angle between the Signals of the respective radiator panels 12, 13 are influenced and pivoted. The radiation direction R can be pivoted within the ZX plane, ie within the pivot plane. The radiator elements 2, 3 are applied together with the wiring 24 on an upper side of a carrier 25. On an underside of the carrier 25, an electrical ground reference surface (not shown) may be provided.

6 shows a further embodiment of the antenna arrangement 1 according to the invention in plan view, in which the two radiator panels 12, 13 are electrically decoupled from one another by means of Wilkinson dividers 27. The radiator elements 2, 3, 4 are arranged in rows 16 and columns 26. By the Wilkinson divider 27, which each have two quarter wavelength lines 29 and a resistor 28, the fed using the feed points 5, 6 radiator panels 12, 13 are electrically decoupled in spite of their galvanic coupling with respect to the high-frequency stage 7.

7 shows in plan view a further embodiment of an antenna arrangement according to the invention with radiator fields 12, 13 and more than two feed points 5, 5 ', 6, 6'. The further feed points 5, 5 ', 6, 6' can serve, for example, to increase a pivot angle of the radiation direction R.

The antenna arrangement 1 according to the invention for receiving and / or transmitting electromagnetic radiation from or in a radiation direction R at an average

Wavelength λ comprises a first radiator field 12 with

Nl first radiator elements 2, a second

Radiator array 13 with N2 second radiator elements 3 and a high-frequency stage 7, which provide or Receiving electrical signals at the central wavelength λ antenna side, a first terminal 8 and a second terminal 9, wherein the first radiator array 12 is connected to the first terminal 8 and the second radiator array 13 is connected to the second terminal 9, and wherein the first 12 and second 13 radiator field have substantially the same polarization properties, wherein the first radiator panel 12 and the second radiator panel 13 have at least one radiator element 4 in common. The inventive transmitting and / or receiving device 10, in particular mobile station, base station or radar, with a baseband processing stage 21 and a high-frequency stage 22 comprises the antenna arrangement 1 according to the invention. The invention is characterized by a high degree of compactness, ease of manufacture, high sensitivity and directional selectivity ,

Claims

claims 1. Antenna arrangement (1) for receiving and / or transmitting electromagnetic radiation from or in a radiation direction (R) at a mean wavelength λ, comprising a first radiator field (12) with Nl first Radiator elements (2), a second radiator array (13) with N2 second radiator elements (3), and a high frequency stage (7), the Providing or receiving electrical Signals at the central wavelength λ antenna side, a first terminal (8) and a second terminal (9), wherein the first radiator array (12) is connected to the first terminal (8) and the second radiator array (13) to the second terminal ( 9), wherein the first (12) and second (13) radiator fields are substantially the same Have polarization properties, and wherein the first radiator field (12) and the second radiator field (13) have at least one radiator element (4) in common. The antenna arrangement (1) according to claim 1, wherein the first terminal (8) defines a first phase center (14) of the first radiator array (12) and the second terminal (9) defines a second phase center (15) of the second radiator field (13), and wherein the two phase centers (14, 15) of the Radiator fields (12,13) less than a first Width (Bl) of the first radiator field (12) and / or less than a second width (B2) of the second radiator field (13) are spaced apart, in particular less than 400%, preferably less than 100%, particularly preferably less than 70%, the central wavelength λ, are away from each other. 3. antenna arrangement (1) according to one of the preceding claims, wherein the first (2) or second (3) Radiator elements in columns (26) and / or in rows (16) are arranged. 4. Antenna arrangement (1) according to one of the preceding claims, comprising one or more further Radiator panels (12 ', 13') with further radiator elements [2 ', 3'), for receiving and / or transmitting electromagnetic radiation at the central wavelength λ. 5. Antenna arrangement (1) according to claim 4, wherein the radiation direction (R), in particular with regard to an azimuth angle and an elevation angle, can be influenced by the further radiator fields. 6. Antenna arrangement (1) according to one of claims 4 or 5, wherein the polarization properties of at least one, in particular at least two, of the further radiator fields (12 ', 13') are different from those of the first (12) and second (13) radiator fields. 7. Antenna arrangement (1) according to one of the preceding claims, comprising one or more Wilkinson Divider (27) for decoupling shared emitter elements (4), rows (16) and / or columns (26). 8. Antenna arrangement (1) according to one of the preceding claims, comprising at least one controllable phase shifter (23) for adjusting the relative phase position of the individual radiator elements (2, 3, 2 ', 3'), the radiator elements (2, 3, 2 ', 3') combined to rows (16) or columns (26) and / or the radiator elements combined to radiator fields (5, 6, 5, ¹ ') (2, 3, 2 ', 3') to each other. 9. Antenna arrangement (1) according to one of the preceding claims, wherein at least one of the following features (al) to (a4) is satisfied: (al) the first or second radiator field is planar; (a2) the first (2,2 ') or second (3,3') Radiator elements are substantially two-dimensional surface; (a3) the first or second radiator field comprises at least 9, in particular at least 25, preferably at least 64, particularly preferably at least 100, Radiator elements; (a4) the first (12) and the second (13) Spotlights are essentially the same design. 10. Antenna arrangement (1) according to one of the preceding claims, wherein the first (2,2 ') or second (3,3 ') emitter elements lie on a grid, the lattice spacing (Dl, D2, D3, D4) advantageously between 20% and 80% of the central wavelength λ, in particular between 40% and 60% of the central wavelength λ, advantageously between 45% and 55% of the mean wavelength λ. 11. Antenna arrangement (1) according to claim 10, wherein a grid spacing (Dl, D3) at an edge (17) of the first (12, 12 ') or second (13,13') radiator field is different, in particular larger as a lattice spacing (D2, D4) in the interior (18) of the radiator field (12, 13). 12. Antenna arrangement (1) according to one of the preceding claims, wherein all radiator elements (2,3) lie substantially in one plane. 13. transmitting and / or receiving device (10), in particular mobile station, base station or radar, with a baseband processing stage (21) and a high-frequency stage (22) comprising an antenna arrangement (1) according to one of claims 1 to 12.