EP1468468A2 - Phase-shifting system and antenna field comprising such a phase-shifting system - Google Patents

Abstract

Disclosed is a phase-shifting system (10) which is used particularly for electrically swiveling the direction of beam of an antenna field comprising several radiators with two planes of polarization. The inventive phase-shifting system comprises two jointly changeable phase shifters (10a,b) with microstrip lines (66, 67) associated thereto. The electrical length of each of said phase shifters (10a,b) can be changed by a dielectric (70) which is slidable above the microstrip lines (66, 67). Such a phase-shifting system offers a simplified design and added functional safety by arranging the microstrip lines (66, 67) of both phase shifters (10a,b) in parallel next to each other and by providing a common slidable dielectric (70) in order to change the electrical length of the microstrip lines (66, 67) of both phase shifters (10a,b).

Description

 DESCRIPTION

PHASE SHIFT ARRANGEMENT AND ANTENNA FIELD WITH SUCH A PHASE SHIFT ARRANGEMENT

TECHNICAL AREA

The present invention relates to the field of RF technology. It relates to a phase shifter arrangement according to the preamble of claim 1 and an antenna field with such a phase shifter arrangement according to the preamble of claim 17.

Such a phase shifter arrangement or antenna field is known, for example, from US-B1-6,310,585. STATE OF THE ART

In the field of mobile radio, antenna fields ("antenna arrays") or antennas have been known for a long time for the equipment of the base stations, in which several individual radiators are arranged one behind the other in an attachment direction and are controlled via a common feed network. In order to be able to take better account of the different conditions at the location of the respective base station and the interaction with other base stations, it has proven to be advantageous to provide the antennas with a possibility for “down tilt”. This can basically be done in a purely mechanical way, in that the antenna is designed to be adjustable at its attachment points on the mast. The disadvantage here is that such a mechanical tilting can only be set and changed with great effort and usually requires climbing the mast.

It has therefore been proposed many times to implement the tilting by electrical means ("electrical down tilt") in that, in the case of a fixed antenna, the individual radiators of the antenna or of the antenna field are controlled with different phases in such a way that the resulting from the superimposition of the phase shift pushed fields of the individual radiators formed radiation lobe is tilted in the desired manner ("phased array"). Examples of such an electrical "down tilt" are known from US-A-6, 198,458 or from US-A-5,801, 600 or from US-A-5,905,462. Special differential (see also DE-A1-199 11 905 or US-A-5,949,303) or other phase shifters are used, which are arranged in the feed network of the antenna between the individual radiators and, for example, together via a linkage by means of a motor drive can be adjusted (see also US-A-5,798,675). The simple, electrically controllable adjustability also offers the possibility of remote adjustment from a control center or the like ("remote tilt control"). Combinations of mechanical and electrical tilting are also conceivable (US-A-5,440,318).

With the newer transmission methods of mobile radio technology with a high data transmission rate, as e.g. Under the abbreviation UMTS, there is an increasing tendency to use dual polarized antennas in order to take advantage of the effect of "polarization diversity", in which data is transmitted several times on radio waves of different polarization to increase the security of transmission can. The radiators in these antennas each have two radiator elements for the two polarizations and are configured, for example, as cross dipoles or correspondingly designed patch radiators.

For the double-polarized antennas or antenna fields, an electrically controlled tilting by means of phase shifters has already been proposed in the above-mentioned publication US-A-6,310,585. For this purpose, a phase shifter (40 in Fig. 1; 440 in Fig. 3) is assigned to each of the two radiator elements of a radiator within the feed network, in which, for example, a microstrip line is covered to a greater or lesser extent by a displaceably arranged dielectric (column 3, lines 61-65; column 5, lines 1-18). Details of the phase shifters and the associated microstrip lines cannot be found in the document.

In US-A-6,310,585, the phase shifters for all radiator elements in one polarization direction are mechanically rigidly coupled to one another by a first rod. The phase shifters for all radiator elements in the other polarization direction are also rigidly mechanically coupled to one another by a second rod. Both rods are in turn rigidly connected to one another by a central support device (415 in FIG. 3) and are driven by a Rjtzej via a toothed rack. In addition, several flexible positioning elements (420 in FIG. 3) are provided, which press the dielectrics onto the microstrip lines underneath. A disadvantage of this known phase shifter arrangement is not only the complex shifting mechanism consisting of a large number of individual parts, but also the separate construction of the individual phase shifters, which requires high accuracy during assembly and thus increased assembly effort with an increased susceptibility to errors.

PRESENTATION OF THE INVENTION

It is therefore an object of the invention to design a phase shifter arrangement of the type mentioned at the outset in such a way that the disadvantages of the known phase shifter arrangements are avoided, and in particular that the structure is simplified and the desired functionality is reliably achieved, and to specify an antenna field with such a phase shifter arrangement.

The object is achieved by the entirety of the features of claims 1 and 17. The essence of the invention is to arrange the microstrip lines of the two phase shifters in parallel and to provide a common, displaceable dielectric for changing the electrical length of these microstrip lines of both phase shifters. In this way, only one single displaceable dielectric is required per radiator, by means of which the electrical length for both polarizations is automatically adjusted synchronously. There is therefore only a single row of dielectrics arranged one behind the other in the direction of installation of the antenna field, which can be displaced simultaneously in a particularly simple manner by means of a single rod extending in the longitudinal direction.

In particular, the microstrip lines and the displaceable arrangement of the dielectric are designed such that the electrical length of the two parallel microstrip lines changes in the same way when the dielectric is displaced Mass changes. This ensures that the radiation lobe always has the same orientation for both polarizations.

In principle, it would be conceivable to shift the dielectrics of the phase shifter arrangements transversely to the direction of attachment of the antenna field. However, the mechanics become particularly simple if, according to a preferred embodiment of the invention, the microstrip lines extend essentially along a longitudinal axis and the dielectric is displaceable in the direction of the longitudinal axis.

The microstrip lines preferably each have at least one center piece which is completely covered by the displaceable dielectric in a first position and is left completely free in a second position. It is favorable for the setting characteristic if the microstrip lines in the middle sections run transversely to the longitudinal direction with a meandering structure, because this leads to a greater change in the electrical length per unit of displacement.

It has already been recognized in US Pat. No. 3,656,179 that the associated wave resistance changes due to the shifting of the dielectric in a stripline arrangement. In order to reduce the change in the wave impedance to a tolerable level, according to another embodiment of the invention it is provided that within the meandering structure there are several line sections running in parallel in the longitudinal direction, and that the microstrip lines change their strip width in the line sections running in the longitudinal direction.

The change in the strip width is preferably designed such that when the dielectric is shifted from the second to the first position, the strip width of the covered line sections, starting from a minimum strip width, increases with increasing coverage up to a maximum strip width, the strip width in particular increasing linearly with the displacement path in the longitudinal direction.

A particularly favorable variation of the wave resistance around an average value results if the minimum strip width is selected such that when covered with the dielectric, the same wave resistance of the microstrip lines results in the area of the minimum strip width as in the area of the maximum strip width without coverage with the Dielectric. This type of change in the stripe width is advantageous for any phase shifter that works with the displacement of a dielectric above a microstrip line, regardless of whether or not several phase shifters have a common dielectric.

In addition, in the longitudinally extending line sections for adapting the characteristic impedance, adapting pieces of different strip width can be arranged.

The phase shifter arrangement according to the invention is further simplified if the microstrip lines of the two phase shifters are arranged and formed on a common printed circuit board. Together with the jointly displaceable dielectric, this results in a high degree of synchronization with a particularly simple structure.

One possible configuration of the printed circuit board is that the microstrip lines of the two phase shifters are mirror-symmetrical to a central axis of the printed circuit board running parallel to the longitudinal axis.

So that the displaceable dielectric is always in a defined position relative to the microstrip lines below it, it is advantageous if the microstrip lines of the two phase shifters and the common dielectric above are pressed flat against one another by means of a spring plate. A particularly uniform contact pressure results if the spring plate is arranged on the underside of the microstrip lines and is electrically insulated from the microstrip lines by an intermediate insulating plate, and if the spring plate has a plurality of individual spring tongues distributed over the surface.

For driving the phase shifters there is preferably provided a slider which is displaceable in the longitudinal direction and which can be actuated manually or by a motor from the outside and which engages with the dielectric. This configuration is particularly simple and reliable and has the advantage of maintaining its position if the motor drive fails.

It has proven itself in practice that a plate with a relative dielectric constant of approximately 10, in particular in the form of a glass fiber-reinforced, organic-ceramic laminate, is used as the dielectric.

A preferred embodiment of the antenna field according to the invention is characterized in that a plurality of jointly displaceable phase shifter arrangements are arranged one behind the other within the feed network, and that connections for connecting the radiators are provided between and after the phase shifter arrangements.

Another preferred embodiment is characterized in that radiators are arranged in the antenna field 2n + 1 (n = 1, 2, 3, ...), that in the associated feed network 2n phase shifter arrangements are arranged one behind the other, that the feed inputs between the n -th and the (n + 1) -th phase shifter arrangement are connected to the feed network, and that all phase shifter arrangements can be operated together, the first n phase shifter arrangements working in opposite directions to the second n phase shifter arrangements. Further embodiments result from the dependent claims.

BRIEF EXPLANATION OF THE FIGURES

The invention will be explained in more detail below on the basis of exemplary embodiments in connection with the drawing. Show it

1 in cross section (FIG. 1A), in top view from above (FIG. 1B) and in longitudinal section (FIG. 1C), a single phase shifter arrangement consisting of two phase shifters according to a preferred exemplary embodiment of the invention;

FIG. 2 shows the base plate of the phase shifter arrangement according to FIG. 1;

3 shows an insulating film of the phase shifter arrangement according to FIG. 1;

Fig. 4, the spring plate of the phase shifter arrangement of FIG. 1 in the

Top view (Fig. 4A) and side view (Fig. 4B);

5 shows an insulating plate of the phase shifter arrangement according to FIG. 1;

6 shows the printed circuit board with the two microstrip lines of the phase shifter arrangement according to FIG. 1;

FIG. 7 the dielectric of the phase shifter arrangement according to FIG. 1;

8 is a top view from above (FIG. 8A) and a side view from the front (FIG. 8B) shows the slide of the phase shifter arrangement according to FIG. 1; 9 shows the top view from two sides (FIGS. 9A and B) of a printed circuit board with 8 phase shifter arrangements according to the invention for an antenna field with a total of 9 radiators; and

Fig. 10 shows the simplified circuit diagram for the antenna field

Fig. 9.

WAYS OF CARRYING OUT THE INVENTION

10 shows the simplified circuit diagram of an antenna field 105, in which the present invention can be used to advantage. The antenna field comprises a total of 9 radiators 106, .., 114, which are arranged one behind the other (one above the other) in a (vertical) mounting direction. Each of the emitters 106, ..., 114 consists of two individual emitter elements 106a, b (the reference numerals for the emitter elements in the emitters 107, ... 114 have been omitted for the sake of clarity). Each of the radiator elements 106a, b is responsible for a direction of polarization. The two polarization directions are usually perpendicular to one another and usually form an angle of 45 ° with the mounting direction of the antenna field 105. The radiators 106, .., 114 are provided both for the emission and for the reception of radio waves.

The radiators 106, .., 114 or radiator elements 106a, b are connected via a feed network 115 to two feed entrances 99a, b, which are arranged within the feed network 115 at the level of the central radiator 110. Each of the two feed inputs 99a, b is assigned to one of the polarization directions and is connected to the corresponding radiator elements. So that the radiators 106, .., 114 form a "phase array" and can emit or record an electrically pivotable beam, phase shifters 91a, b, .., 98a, b are arranged in pairs in the feed network 115. Each pair of phase shifters 91a, b ..., 98a, b forms a phase shifter arrangement. The adjustment of the two phase shifters of a pair of phase shifters or a phase slide arrangement is synchronous, as indicated in Fig. 10 by the dashed connecting lines within each pair. All phase shifter pairs 91a, b, .., 98a, b are actuated simultaneously by a manually or motor-driven connecting tongue 116 running in the longitudinal direction (mounting direction), which is also shown in broken lines in FIG. 10. The change in the phase shift in the phase shifters 95a, b, .., 98a, b arranged below the feed inputs 99a, b takes place in the opposite direction to the change in the phase shift in the phase shifters 91a, b, .., 94a, arranged above the feed inputs 99a, b. b (ie, an increase in the phase shift at the bottom corresponds to a decrease in the phase shift at the top, and vice versa), which is indicated in FIG. 10 by the differently oriented arrows in the phase shifters.

The middle one of the 9 radiators 106, .., 114, namely the radiator 110, is directly connected to the feed channels 99a, b and therefore works with a constant phase. A pair of phase shifters is assigned to the remaining 8 radiators 106, .., 109 and 111, .., 114. Since the phase shifter pairs 91a, b, .., 98a, b are connected in series within the feed network 115, the individual phase shifts add up, starting from the center. If all phase shifters are of the same design, the phase shift to the outside increases in the same steps: the signal fed into the feed inputs 99a, b reaches the radiator 109 with a single phase shift, the radiator 108 with a double phase shift, the radiator 107 with one triple phase shift, and the radiator 106 with a four-fold phase shift. The same applies to radiators 111 to 114.

An individual pair of phase shifters or a single phase shifter arrangement now preferably has a structure as shown in the exemplary embodiment of FIGS. 1 to 8, a completely assembled arrangement being shown in different views in FIG. 1, while FIGS. 2 to 8 the individual elements of the arrangement of Fig. 1 show in their order within the arrangement. The printed circuit board 60 shown in FIG. 6 with the microstrip lines 66, 67 only represents the partial section of a longer printed circuit board 90, as is shown in FIG. 9 for the entire antenna field 105 from FIG. 10.

The printed circuit board 60 (FIG. 6), which consists, for example, of a base material of 0.5 mm thickness with a double-sided 35 μm Cu layer, has a continuous Cu coating on the underside and the one shown on the top to a central axis 11 mirror-symmetrical conductor tracks, which form the microstrip lines 66, 67. The printed circuit board 60 is arranged in the phase shifter arrangement 10 of FIG. 1 between a (lower) base plate 20 (FIG. 2) and an (upper) slide 80 (FIG. 8) such that the conductor tracks of the microstrip lines 66, 67 are on the Side of the slider 80. The base plate 20, which can be designed, for example, as an aluminum plate, has on the sides two fastening tabs 21, 22 with corresponding fastening holes 23, 24, by means of which they can be screwed onto an antenna housing.

The printed circuit board 60 is fixed with respect to the base plate 20. This is achieved in that two tabs 25, 26 are bent upwards at right angles on the base plate 20 and engage in corresponding openings 64, 65 in the printed circuit board 60 (FIG. 6). In the printed circuit board 60 there are also three spaced-apart guide openings 61, .., 63 running parallel to the central axis 11 in the form of elongated holes, into which the slide 80 engages with correspondingly shaped and arranged engagement cams 81, .., 83 (FIG 1; Fig. 8). The guide openings 61, .., 63 define the displacement range of the slide 80 relative to the printed circuit board 60.

The slide 80, which for example consist of a plastic and can be an injection molded part, additionally has two side guides 86, 87 which extend over the side edge of the printed circuit board 60. On its upper side of the slide 80, two driver cams 88, 89 are formed in succession in a depression in the longitudinal direction, on which an actuating element (not shown) for the slide can act. Furthermore, two cutouts 84, 85 are provided on the slide 80. see to make room for the tabs 25, 26 which protrude from below through the printed circuit board 60.

The actual phase shifters 10a, 10b of the phase shifter arrangement 10 are formed by the interaction of the microstrip lines 66, 67 with a dielectric 70 which is displaceably arranged on the upper side of the printed circuit board 60. The dielectric 70 shown individually in FIG. 7 is made, for example, of an organic ceramic laminate of the type CER-10, as is offered by the US company Taconic, Petersburgh, NY (USA). The fiberglass-reinforced laminate filled with ceramic has a DK of 10 and very good mechanical properties. A plate of this material with a thickness of approximately 0.64 mm is used. Other dielectrics are also conceivable. 7, the dielectric 70 has three spaced-apart, circular engagement openings 71, .., 73, into which the slide 80 engages with its engagement cams 81, .., 83. In this way, the dielectric 70 is fixed relative to the slide 80 and is moved together with the slide 80. Furthermore, two cutouts 74, 75 which are comparable in shape and function to the cutouts 81, 82 of the slide 80 are provided in the dielectric 70.

The interaction of the microstrip lines 66, 67 and the dielectric 70 takes place essentially in the area of meandering middle pieces 66b, 67b of the microstrip lines 66, 67, which are each arranged between connecting pieces 66a, c and 67a, c and run transversely to the central axis 11 (FIG 6). Each of the middle pieces 66b, 67b consists of several (in the example of FIG. 6 from 5) line sections 66d,... H running parallel to the central axis 11, which are connected to one another to form the meandering pattern on alternating sides by U or V shaped arc pieces are connected. Within the line sections 66d, .., h, the line width varies linearly with the length and decreases from left to right. Since the dielectric 70 with the left edge moves exactly in the region of the line sections 66d,... H when moving, regions of the line sections 66d, .., h are covered or not covered with different line widths when the dielectric is moved. The variation in the line width of the line sections 66d, .., h has a special reason: In order to maintain the (usual) characteristic impedance of the microstrip lines 66, 67 of 50 ohms, the line width for the materials and dimensions used is approximately 1.5 mm ( without overlying dielectric). In the area of the overlying dielectric, however, because of the dielectric for a characteristic impedance of 50 ohms, only a line width of about 0.98 mm is required. If the line width outside the coverage area of the dielectric is set at 1.5 mm and in the area of constant coverage at 0.98 mm and a linear transition between these two extreme values is assumed in the line sections 66d,... H in between, the deviation varies the actual characteristic impedance when the dielectric 70 is shifted by the mean value 50 ohms, the characteristic impedance being more than 50 ohms when the dielectric 70 is pushed to the left far beyond the line sections 66d,... h and less than 50 ohms when the dielectric 70 is only slightly pushed over the line sections 66d, .., h. Since only the absolute value of the difference is relevant for the (undesired) mismatch, but not the sign, a larger displacement range of the dielectric and thus a larger phase shift over a larger frequency range can be obtained using the maximum permitted mismatch. In addition, the electrical properties can be optimized by providing widened adaptation pieces 68, 69 in the middle pieces 66b, 67b (FIG. 6).

The two microstrip lines 66, 67 are - as can easily be seen in FIG. 6 - formed and arranged mirror-symmetrically to the central axis 11. The dielectric 70 is chosen so wide that when it is moved in the direction of the central axis 11, it covers or releases the meandering central pieces 66b, 67b of the microstrip lines 66, 67 in the same way. In this way it is possible to achieve a synchronization between the two phase shifters 10a and 10b and a largely identical phase shifts in both phase shifters 10a, b without great effort and with high functional reliability. An important part of the functional reliability is, however, that the dielectric 70 lies as close as possible to the surface of the printed circuit board 60 carrying the microstrip lines 66, 67 without an air gap. This is achieved by a flat spring plate 40 (FIGS. 4A, B), which is arranged between the base plate 20 and the printed circuit board 60 and presses the printed circuit board 60 from below against the dielectric 70 held in the slide 80. The spring plate 40 - like the base plate 20 - has lateral fastening tabs 41, 42 with corresponding fastening holes 43, 44 which are aligned with the fastening holes 23, 24 of the bottom plate 20. A large number of individual spring tongues 45, which have been produced, for example, from the spring plate 40 by a stamping and bending process, are arranged next to one another over the surface of the spring plate 40. The spring plate 40 is electrically insulated from the base plate 20 by an interposed, thin insulating film 30 (FIG. 3), which is adapted with lateral fastening tabs 31, 32 and fastening holes 33, 34 of the base plate 20 and the spring plate 40. The spring plate 40 is also electrically insulated from the lower Cu ground layer of the printed circuit board 60 by an intermediate, for example 0.5 mm thick insulating plate 50 (FIG. 5) against which the spring tongues 45 press. The insulating plate has openings 54, 55 through which the tabs 25, 26 of the base plate 20 are inserted for fixing. The slot-like guide openings 51, .., 53 are analogous in function and design to the guide openings 61, .., 63 in the printed circuit board 60.

The exemplary embodiment shown in FIGS. 1 to 8 relates only to a phase shifter arrangement comprising two phase shifters 10a, b, which is accordingly only suitable for adjusting a doubly polarized radiator. If - as shown in FIG. 10 - an antenna field 105 comprises more than two, for example 9, radiators 106 ... 114, and several, in example 8, phase shifter arrangements are required for the electrical pivoting of the antenna beam, these phase shifter arrangements are combined with the dining network 1 15 preferably integrated on a single printed circuit board. Such a printed circuit board 90 for a total of 9 radiators and 8 phase shifter arrangements is shown in FIG Fig. 9 reproduced. On this printed circuit board 90, two microstrip lines 90a, b are formed with branches, which are symmetrical with respect to the central axis 11, and which simultaneously form a feed network with a distribution of the power over a plurality of antenna connections 102a, b, 9B, only the antenna connections for 4 radiators are provided with reference symbols; in total there are antenna connections for 9 radiators or 18 radiator elements).

Analogous to FIG. 6, meandering center pieces 91a, b, .., 98a, b are formed within the feed network of microstrip lines 90a, b, each of which is part of a phase shifter arrangement 91, .., 98 comprising two phase shifters. The feed inlets 99a, b are arranged in the middle of the printed circuit board 90. Each of the phase shifter assemblies 91,... 98 - as in FIGS. 1 to 8 - includes a dielectric which can be displaced by means of a slider, a base plate and an insulated spring plate. Correspondingly, guide openings 100 and openings 101 are provided in each of the phase shifter arrangements 91,..., 98 for the engagement of the base plate. The (nine) sliders of all phase shifter assemblies 91,..., 98 are in engagement with a common actuating element (not shown) which extends along the central axis 11 over the entire printed circuit board 90 and can be moved in the longitudinal direction manually or by a controlled motor drive can.

In summary, the following can be said:

Phase shifters are required to achieve a variable down tilt in an antenna field (array antenna). The main lobe of the antenna must be able to be lowered at least to the first zero above the horizon. The following requirements must be met in mobile radio technology (GSM, UMTS):

With large antennas, the down tilt must be able to be changed between 0 ° and approx. 8 °; To do this, the phase shifter must be able to change the phase continuously between 0 ° and approx. 45 °. With small antennas, the down tilt must be able to be changed between 0 ° and approx. 16 °; To do this, the phase shifter must be able to change the phase continuously between 0 ° and approx. 85 °.

There are several ways to change the phase. The following relationship applies between the electrical and the mechanical length of a cable:

lelek - tmech &

lelek The electrical length is proportional to the phase: φ = - 360 °

To change the phase, the mechanical length or the ε _{r can be} changed.

A patent has already applied for a phase shifter with a change in the mechanical length of the line.

A phase change by changing the ε _r can be achieved in the case of a microstrip line (microstrip line) by placing a dielectric on the line (see DE-A1 -199 11 905).

According to the present solution, a plurality of line sections lying parallel to one another are connected to one another by a 180 ° corner to form a meandering structure. A dielectric with a high ε _{r is} pushed over this line structure, a common dielectric being used for two phase shifters arranged next to one another. The maximum possible phase shift is given by the number of line sections and their length, which at the same time corresponds to the sliding path of the dielectric.

A phase shift of 46 ° is achieved with 5 parallel line sections, and a phase shift of 65 ° is achieved with 7 parallel line sections reached. In order to achieve an even larger phase shift, several phase shifters can be connected in series.

The phase shifter can be integrated very well into a feed network due to an odd number of parallel line sections. However, the phase shifter can also be implemented with an even number of lines, which can be more advantageous for other applications.

Each individual line section in the phase shifter has a linearly variable line width (is linearly tapered). In the 0 ° position of the phase shifter (the dielectric is not above the line sections), the line width is narrower and so wide that the system impedance (50 Ω) is given together with the dielectric pushed over it. At the other end of the line sections, the line width corresponds to the normal microstrip. Despite the tapered line sections, a mismatch occurs depending on the position of the sliding dielectric. The mismatch can be compensated for by small adjustment pieces ("stubs") in the line structure.

The mechanics of the phase shifter are as follows: An aluminum base plate is screwed onto the antenna housing and positions the print (the printed circuit board) with the cable structure using 2 bent tabs. The sliding dielectric is on the print. Between the aluminum plate and the print is a spring plate which presses the print against the dielectric. The print (mass), the spring plate and the aluminum plate are isolated from each other by additional insulators.

A substrate with a high ε _r can be used as the dielectric. This thin plate is held by an additional plastic part (slide), which also has driver cams for the slide device. It is also possible, by choosing a suitable plastic or ceramic, to realize the dielectric plate and the plastic part from one piece. The phase can be set using a manually or electrically operated drive.

LIST OF REFERENCE NUMBERS

10 phase shifter arrangement 10a, b phase shifter

11 central axis 20 base plate 21, 22 mounting bracket

23.24 mounting hole

25.26 rag

30 insulating film

31, 32 mounting bracket 33, 34 mounting hole

40 spring plate

41, 42 mounting bracket

43.44 mounting hole

45 spring tongue 50 insulating plate

51, .., 53 guide opening (slot)

54.55 opening

60 printed board

61, .., 63 guide opening (slot) 64.65 opening

66.67 microstrip line

66a, 67a connector

66b, 67b middle section (meandering)

66c, 67c connecting piece 66d, .., h line section

68.69 adapter

70 dielectric 71 .... 73 access opening

74.75 recess

80 sliders

81, .., 83 engagement cams

84.85 recess

86, 87 side guide

88.89 drive cams

90 printed circuit board

90a, b microstrip line

91, .., 98 phase shifter arrangement

91a, b, .., 98a, b phase shifter (center piece)

99a, b dining entrance

100 guide opening

101 opening

102a, b, .., 104a, b antenna connection

105 antenna field

106, .., 114 spotlights

106a, b radiator element

115 Dining network

115a, b Zweig (dining network)

116 connecting tongue

Claims

1. phase shifter arrangement (10; 91, .., 98), in particular for the electrical pivoting of the radiation direction of a plurality of radiators (106, .., 114) with two

Antenna field (105) comprising polarization planes, which phase shifter arrangement (10; 91, .., 98) two mutually changeable phase shifters (10a, b; 91a, b, .., 98a, b) with associated microstrip lines (66, 67; 90a, b ), the electrical length of which can be changed in each case by a dielectric (70) arranged displaceably over the microstrip lines (66, 67; 90a, b), characterized in that the microstrip lines (66, 67; 90a, b) of both phase shifters ( 10a, b; 91a, b, .., 98aib) are arranged in parallel next to one another, and that in order to change the electrical length of the microstrip lines (66, 67; 90a, b) both phase shifters (10a, b; 91a, b, .., 98a, b) a common, displaceable dielectric (70) is provided.

2. Phase shifter arrangement according to claim 1, characterized in that the microstrip lines (66, 67; 90a, b) and the displaceable arrangement of the dielectric (70) are designed such that the electrical length of the two parallel microstrip lines (66, 67; 90a , b) changes when moving the dielectric (70) to the same extent.

3. phase shifter arrangement according to one of claims 1 or 2, characterized in that the microstrip lines (66, 67; 90a, b) extend essentially along a longitudinal axis (11), and that the dielectric (70) in the direction of the longitudinal axis (11) is displaceable.

4. phase shifter arrangement according to claim 3, characterized in that the microstrip lines (66, 67; 90a, b) each have at least one center piece (66b, 67b; 91 a, b, .., 98a, b), which of the displaceable dielectric (70) is completely covered in a first position and left completely free in a second position.

5. phase shifter arrangement according to claim 4, characterized in that the microstrip lines (66, 67; 90a, b) in the middle pieces (66b, 67b; 91 a, b, .., 98a, b) transverse to the longitudinal direction (11) with a meandering structure.

6. phase shifter arrangement according to claim 5, characterized in that within the meandering structure a plurality of parallel in the longitudinal direction (11) extending line sections (66d, .., h) are provided, and that the microstrip lines (66, 67; 90a, b) in the line sections (66d, .., h) running in the longitudinal direction (11) change their strip width.

7. phase shifter arrangement according to claim 6, characterized in that when moving the dielectric (70) from the second to the first position, the strip width of the covered line sections (66d, .., h), starting from a minimum strip width, with increasing coverage increases up to a maximum stripe width.

8. phase shifter arrangement according to claim 7, characterized in that the strip width increases linearly with the displacement path in the longitudinal direction (11).

9. phase shifter arrangement according to one of claims 7 or 8, characterized in that the minimum strip width is selected so that when overlapping with the dielectric (70) in the area of the minimum strip width the same characteristic impedance of the microstrip lines (66, 67; 90a, b), as in the area of the maximum strip width without overlap with the dielectric (70).

10. phase shifter arrangement according to one of claims 6 to 9, characterized in that in the longitudinal direction (11) extending line Ab- cuts (66d, .., h) to adjust the wave resistance, adaption pieces (68, 69) of different strip width are arranged.

11. Phase shifter arrangement according to one of claims 1 to 10, characterized in that the microstrip lines (66, 67; 90a, b) of the two phase shifters (10a, b; 91a, b, .., 98a, b) on a common one Printed circuit board (60, 90) are arranged and formed.

12. Phase shifter arrangement according to claim 11, characterized in that the microstrip lines (66, 67; 90a, b) of the two phase shifters

(10a, b; 91a, b, .., 98a, b) are mirror-symmetrical to a central axis (11) of the printed circuit board (60, 90) running parallel to the longitudinal axis.

13. Phase shifter arrangement according to one of claims 1 to 12, characterized in that the microstrip lines (66, 67; 90a, b) of the two

Phase shifters (10a, b; 91a, b, .., 98a, b) and the common dielectric (70) lying above them are pressed flat against one another by means of a spring plate (40).

14. phase shifter arrangement according to claim 13, characterized in that the spring plate (40) on the underside of the microstrip lines (66, 67; 90a, b) and arranged by an intermediate insulating plate (50) of the microstrip lines (66, 67; 90a, b ) is electrically insulated, and that the spring plate (40) has a plurality of individual spring tongues (45) distributed over the surface.

15. phase shifter arrangement according to one of claims 1 to 14, characterized in that a in the longitudinal direction (11) slidably guided, externally manually or motor-operated slide (80) is provided, which is in engagement with the dielectric (70).

16. Phase shifter arrangement according to one of claims 1 to 15, characterized in that a plate with a relative dielectric constant of about 10, in particular in the form of a glass fiber reinforced, organic-ceramic laminate, is used as the dielectric (70).

17. antenna field (105) with a plurality of radiators (106, .., 114) arranged one behind the other in a longitudinal direction (11), which radiators (106, .., 114) each have two radiator elements (106a, b) provided for different polarization planes and which emitters (106, .., 114) are connected via a feed network (115; 115a, b) to two feed entrances (99a, b), characterized in that within the feed network (115; 115a, b) Phase shifter arrangements (10; 91, .., 98) arranged according to one of claims 1 to 16 and assigned to individual ones of the radiators (106, .., 114).

18. Antenna field according to claim 17, characterized in that within the feed network (115; 115a, b) several phase shifter arrangements (10; 91, .., 98) which can be displaced together are arranged one behind the other, and that between and after the phase shifter arrangements (10; 91 , .., 98) connections (102a, b, .., 104a, b) are provided for connecting the radiators (106, .., 114).

19. Antenna field according to claim 18, characterized in that in the antenna field 2n + 1 (n = 1, 2,3, ...) radiators (106, .., 114) are arranged that in the associated feed network (115; 115a, b) 2n phase shifter arrangements are arranged one behind the other, that the feed inputs (99a, b) between the nth and (n + 1) th phase shifter arrangement are connected to the feed network (115; 115a, b), and that all phase shifter arrangements can be actuated together, the first n phase shifter arrangements working in opposite directions to the second n phase shifter arrangements.

20. Antenna field according to one of claims 17 to 19, characterized in that the feed network (115, 115a, b) and the phase shifter arrangements (10; 91, .., 98) are arranged on a common printed circuit board (90).