DE2007921A1 - Antenna arrangement - Google Patents

Description

A n t e n n e n a n o r d n u n g The invention relates to an antenna arrangement, especially for spacecraft, with a Pundttrahlan antenna and a reflector for reshaping the characteristics of the directional antenna into a directional characteristic.

Used for the transmission of messages over longer distances generally use of directional antennas having a considerable antenna gain made. The use of such antennas in spin-stabilized spaceflight requires an omnidirectional antenna in conjunction with a suitable reflector is designed as a directional antenna. The orientation of the directional antenna, a corresponding Assuming the arrangement of the omnidirectional antenna, it is done here by an opposing antenna Movement of the reflector around the spacecraft's spin axis.

For this purpose, the reflector is rotatably arranged in a bearing and driven by a tracking motor via suitable control electronics. Fails the reflector tracking, then operation via the directional antenna is no longer possible possible. From the American patent 3 341 151 it is known by blasting off and thus making the reflector ineffective an auxiliary operation via the now in to maintain an omnidirectional converted directional antenna. The blasting off of the reflector brings with it considerable risks and requires about it.

in addition, a considerable mechanical effort. An independent one Arrangement of the directional antenna and the omnidirectional antenna required for auxiliary operation one above the other in the direction of the spin axis causes: considerable difficulties, where 1. with regard to the available space, the weight, the strength, the cable routing, the thermal behavior and the moment of Trigness are tight limits. Also other separate arrangements of the omnidirectional antenna, for example on the opposite one Side of the spacecraft, retire for similar or electrical reasons usually off.

The invention is based on the object for a round beam operation and an antenna arrangement that enables directional beam operation is a particularly simple one and to specify a safe solution that enables the overall antenna to be constructed in a compact manner and in particular find application as an antenna for spin stabilized spacecraft can.

This object is achieved according to the invention in that two, separate Omnidirectional antennas with feed lines with mutually orthogonal linear antennas Polarization are combined into a rod-shaped structural unit, and that the reflector is designed in such a way for a polarization-dependent reflection behavior is that it is practically only effective for one of the two omnidirectional antennas.

The invention is based on the knowledge that with the help of two separately fed omnidirectional antennas with mutually orthogonal linear polarization a compact antenna construction is possible with both antennas by suitable design of the reflector can be electrically decoupled from one another.

When using the antenna arrangement according to the invention for a spin-stabilized Space probe it is necessary to align the reflector with the rod axis of the omnidirectional antenna to store coincident axis rotatably, since here only through one to the spin direction counter-rotating movement of the reflector a local alignment of the directional antenna is possible.

The compact structure of the antenna arrangement is special then promoted when the separate feed lines to the two omnidirectional antennas take place via coaxial lines arranged concentrically to one another.

In a first basic embodiment according to the invention, one is Omnidirectional antenna of the omnidirectional antenna unit a rod-shaped linear radiator, in the center of which is the second omnidirectional antenna.

The linear radiator can advantageously be a slotted, be designed as a coaxial line, the center in a double cone antenna transforms.

Another advantageous embodiment is a linear radiator a group of colinear dipoles, in the center of which a slot radiator is arranged is.

A reflector for polarization-dependent reflection behavior can be easily made of thin straight or curved meta realize flat strips or bars.

When designing the omnidirectional antennas as rod-shaped linear radiators, i whose Zehlbats is the second omnidirectional antenna. does it make sense to the The reflector is designed as a parabolic of revolution with the second omnidirectional antenna at its focal point is arranged.

If the second omnidirectional antenna is a double cone antenna, then lie the metallic strips or rods forming the reflector in planes passing through go the rod axis of the omnidirectional antenna unit. Is the second omnidirectional antenna on the other hand a slot antenna, then weigh the metallic ones forming the reflector Strips or rods in planes which are defined by a width perpendicular to the rod axis of the omnidirectional antenna aligned axis containing the focal point.

At. A second basic embodiment consists of the two omnidirectional antennas of two evenly distributed over the length of the rod-shaped omnidirectional antenna unit and nested radiator groups. Here are for both heater groups separate supply lines arranged concentrically to one another and form a double coaxial line, whose axis of symmetry coincides with the axis of symmetry of the omnidirectional antenna unit.

In a first preferred embodiment for this second The basic version consists of one radiator group from-collinear Dipoles and the other radiator croup of tridipoles.

The 1fridipoles are useful in the extension of the omnidirectional antenna unit arranged between two successive dipoles. The dipoles of one group of radiators are to the outer and the tridipoles of the other radiator group to the inner coaxial line the double coaxial line switched on, with the outer coaxial line in the area the connections of the tridipoles are provided with # / 4 blocking circuits.

Another advantageous option is to use one at a time Dipole of one radiator group with a tridipole of the other radiator group in put together in such a way that the tridipole extends in the extension of the dipole rnd with it the l-andbeam antenna unit is arranged between the two dipole halves and here the dipoles of one emitter group to the outer and the tridipoles the other radiator group to the inner coaxial line of the double coaxial line are turned on.

Another preferred embodiment for the second basic embodiment consists of dipoles arranged collinearly as a radiator group and as others Radiation group to provide slot emitters, each of which has several slot emitters has evenly distributed longitudinal slots on the circumference of the omnidirectional antenna unit. In this case the dipoles of one radiator group are attached to the inner and the Connect the slot radiator of the other radiator group to the outer coaxial line of the double coaxial line attached and for this purpose the outer coaxial line in the field of Provide the connections of the dipoles with # / 4 blocking circuits.

If the omnidirectional antenna unit is optimally designed, overlap the dipoles of one radiator group and the slot radiators of the other radiator group each other. In order to prevent the two from interfering with each other in this case To switch off radiator groups, the dipoles are designed as longitudinally slit dipoles, their longitudinal slots with the slots of the Schlitzstrah-1er brought to cover are.

The construction of the rod-shaped omnidirectional antenna unit with the help of two nested radiator groups requires a reflector with a cylindrical parabolic Shape, made up of bars or strips arranged parallel to the focal line and the rod-shaped omnidirectional antenna unit is arranged in its focal line is.

To get the highest possible proportion of the emitted electromagnetic Energy in the focal point of the rotating parabolic reflector or in the focal line to bundle the second omnidirectional antenna arranged on the cylinder parabolic reflector, it is necessary to make the reflector so that its focal point or its Focal line in the axis of rotation placed as far inwards as possible towards the vertex is. Such a "deep" reflector brings certain impairments to the omnidirectional antenna with himself. For some applications it makes sense to use a deep one instead of this one Reflector to provide a "flat" reflector, and the resulting loss of focus to compensate with an auxiliary reflector.

It should be noted that the radiator groups nested in one another existing omnidirectional antenna unit in the various versions described can of course also be used without a reflector. Possible applications are given wherever, on the one hand, a compact embodiment of an omnidirectional antenna with increased gain for double radiation or double reception is required, or where it matters, for sending and.

To make use of separate antennas for reception.

To ligand of exemplary embodiments shown in the drawing the invention is to be explained in more detail below. In the drawing mean Fig. 1 shows a first embodiment of a first basic embodiment according to the Invention, FIG. 2 shows a section of the rod-shaped omnidirectional antenna unit 1, 3 show a second exemplary embodiment for a first basic embodiment according to the invention.

4 shows a third embodiment for a first basic embodiment according to the invention, Fig. 5 shows a first embodiment for a second basic embodiment according to the invention, Fig. t shows a partial section of the omnidirectional antenna unit FIG. 5, FIG. 7 a partial section of the omnidirectional antenna unit according to FIG. 5, FIG. 8 and 9 partial sections of a second embodiment for a second basic embodiment according to the invention, 10, 11 and 12 partial sections of a third Exemplary embodiment for a second basic embodiment according to the invention.

The exemplary embodiment according to FIG. 1 shows the antenna platform 1 a spin-stabilized space probe, which consists of two omnidirectional antennas Omnidirectional antenna unit 2 coincides with its rod axis with the spin axis of the probe One circular antenna consists of a group of one on top of the other Slot radiators, their longitudinal slots with 3 and the longitudinal slots for radiation stimulating coupling pins are denoted by 4. The other omnidirectional antenna of the omnidirectional antenna unit is a double-cone antenna placed in the center of the rod-shaped antenna unit ,, which are arranged at the focal point of the reflector 6 representing a parabolic of revolution is. The reflector b is with the foot-side aging 7 in the bearing 8 with follow-up motor in the rod axis of the omnidirectional antenna unit and thus in the spin axis of the spin stabilized Space probe rotatably mounted. The tracking motor moves the reflector 6 against the Spin motion of the space probe in the sense of a fixed spatial orientation, the from the reflector 6 and the double cone antenna 5 existing directional antenna.

The partial longitudinal section of the omnidirectional antenna unit according to FIG. 1 in The area of the double cone antenna leaves the separate supply lines or feed lines for the two omnidirectional antennas. The separate supply lines for the two Omnidirectional antennas consist of coaxial lines in a concentric arrangement, the in hereinafter referred to as double coaxial line. the e Lrr coaxial line with the outer conductor 9 and the inner conductor 1G serves the upper one Half of the slot radiator group as a supply line, while the coaxial line with the Outer conductor 1 and the tubular conductor 12, which here. in the area of the double cone antenna merges into the outer conductor 9 of the first-mentioned coaxial line, the feed line for the double cone antenna forms. -The coaxial line with the conductors 11 and 11 'serves as Feed to the lower half of the slot radiator group.

The two omnidirectional antennas forming the omnidirectional antenna unit are dimensioned for mutually orthogonal linear polarization. The direction of polarization of the electrical two E is in Fig. 1 for both antennas by an arrow specified. According to this, the omnidirectional antenna consisting of the slot radiator group points a linear horizontal and the double cone antenna a linear vertical polarization on. Der.Re reflector 6 must accordingly with regard to its desired reflection behavior be sized so that it matches the vertical linear polarization of the double cone antenna reselected and for the horizontal linear polarization of the slot radiator group is practically ineffective. As has already been stated in the introduction, achieved in that the metallic strips or rods that make up the reflector 6 consists, lie in planes passing through the rod axis of the round steel antenna unit walk.

The combined directional and omnidirectional antenna shown in FIG. 3 differs from the embodiment according to Fig. 1 in that that the one omnidirectional antenna unit instead of a slot radiator group a group of collinear ones arranged in the rod axis of the omnidirectional antenna unit Dipoles 13, for example half-wave dipoles, are in the center of the omnidirectional antenna unit arranged second omnidirectional antenna is a slot radiator 14. The polarization of the electric field E is here compared to the all-guide example according to Fig. 1 swapped, and that now has the one in the center of the omnidirectional antenna unit arranged slot radiators a linear horizontal and the dipole group a linear vertical polarization. This requires the formation of the rods or strips constructed reflector 6 'representing a parabolic of revolution in such a way that the metallic strips or rods lie in planes that are perpendicular to one another aligned with the rod axis of the omnidirectional antenna unit and containing the focal point Axis go.

In Fig. 3 is on the one hand a horizontal im in broken line Area of the slot radiator 14 arranged dielectric plate 15 and one of the reflector 16 deviating from the parabolic shape of revolution is indicated. The dielectric Plate 15 brings about a stronger focus of the slot radiator 14 and allows as a result, a more favorable design of the reflector in terms of a shape that lies between a parabolic of revolution and a parabolic cylinder. Through the in the Fig. 1 and 3 illustrated embodiment of the reflector 6 and 6 ', in which the The focal point of the parabolic of revolution is practically in the middle of the line connecting The vertex and reflector opening will be a good bundling the reached in the focal point arranged second omnidirectional antenna, but can with this Reflector form certain impairments of a slot radiator and a Dipole group existing first omnidirectional antenna occur.

he further possibility, from the deep parabola of the reflector is shown in FIG. 4. 4 again shows an omnidirectional antenna unit 2 with a double cone antenna arranged in the center according to FIG. 1, in which instead of a deep parabolic rotating reflector, a reflector 17 with a flat parabolic rotating shape is provided whose focal point lies in the aperture plane. The desired high The directional antenna is bundled here with the help of a spherical auxiliary reflector 18 reached, which is arranged in front of the double cone antenna and its direct radiation on the reflector 17 throws back.

In the first embodiment shown in Fig. 5 for a The second basic embodiment is combined for both to form an omnidirectional antenna unit Omnidirectional antennas made use of a group of radiators. With the omnidirectional antenna unit 2 'according to FIG. 5, one emitter group consists of collinear ones in the rod axis arranged half-wave dipoles 19 and the other radiator group of tridipoles 20.

The two emitter groups are nested in one another in such a way that in the extension of the omnidirectional antenna unit 2 'between two half-wave dipoles 19 a tridipole consisting of three curved half-wave dipoles 20th is arranged. The Reflekto-r 21 has to be discussed here, as with the following Execution examples, the shape of a cylindrical parabolic, in whose focal line the Omnidirectional antenna unit 2 'is arranged. The reflector 21 consists of parallel thin rods 22 arranged at its focal line for reasons of obscurity the rods 22 are omitted in the area of the omnidirectional antenna unit 2 ' The embodiment shown in FIG. 4 with a flat rotating parabolic reflector it is also possible here to give the cylindrical parabolic reflector a flat shape and the resulting larger radiation losses compared to a deep shape to compensate by means of an auxiliary reflector, which in this case, for example, has a parallel to the andbeam antenna unit may be a rod disposed in front of it.

The two heater groups are fed, as is the case with the Embodiments according to FIGS. 1 to 4, via one in the rod axis of the runus beam antenna unit 2 'running double coaxial line. The connections for the half-wave dipoles of the one emitter group on the one hand and the tridipoles of the other emitter group on the other are shown in detail in FIGS. 6 and 7.

6 shows part of a longitudinal section in the axial direction of the omnidirectional antenna unit 2 'according to FIG. 5, in which, for the sake of simplicity, only the axis of symmetry upper half of the section is indicated. The half-wave dipoles 19 are annular Slots 22 in the outer conductor of the outer conductor 11 and the rohrf ò-shaped Conductor 12 fed as the inner conductor of the existing coaxial line. The? Feeding points. are in the middle of the half-wave dipoles each consisting of two # / 4 parts 19 provided. The tridipole arranged between the two half-wave dipoles 19 20 .from the inner conductor 10 and the tubular conductor 12 of the former Coaxial line connected as an outer conductor. To the short circuit in the out of the outer conductor 11 and the tubular conductor 12 existing coaxial line at the point of implementation To compensate the inner coaxial line to the tridipole 20, the outer coaxial line in the area of the inner coaxial line passing through to the outside, A / 4 blocking circuit-e 23 on. To achieve the highest possible gain for a given length of the omnidirectional antenna unit to achieve, the half-wave dipoles 19 are one above the other at a distance of 3/4 # o, with the wavelength \ o in air. To ensure in-phase supply of the successive Reaching half-wave dipoles at this distance is the space between Inner and outer conductors of the outer coaxial line with a dielectric 24 such Condition filled in that the wavelength in the coaxial line is just the same is the distance between two consecutive feed points.

FIG. 7 shows the section A. / A 'indicated in FIG. 6, which shows the structure of a tridipole 20 can be better recognized.

The tridipole consists of three added to a circle in one plane in-phase fed curved half-wave dipoles 20 '. Each half-wave dipole 20 ' is made up of two # / 4 pieces. The feeding points of these half-wave dipoles 20 'is made as in the half-wave dipoles 19 according to FIG. 6 in the middle.

The nesting of the half-wave dipoles and tridipoles two radiator groups to a rod-shaped omnidirectional antenna unit can also take place in such a way that the tridipoles 20 are each between two A J4 sections a half-wave dipole are arranged. A partial sectional drawing corresponding to FIG. 6 for such an embodiment Fig. 8 shows the implementation of the inner from the Inner conductor 10 and the tubular conductor 12 existing coaxial line through the consisting of the tubular conductor 12 and the outer conductor 11 outer coaxial line through to the connection points of the half-wave dipoles 20 'of the tridipole 20 takes place at the location where the half-wave dipoles 19 are fed, which is in contrast to the embodiment According to FIG. 6, A / 4 trap circuits can be dispensed with. The connection of the tubular Conductor 12 with the right 2/4-part of the half-wave dipole 19 takes place via the Connector 25. From Fig. 9, which is a plan view of the shown in longitudinal section 8 represents, on the one hand, the feed point for the half-wave dipole 19, consisting of the connector 25 and the tubular conductor 12, as well the feed point for one of the half-wave dipoles of the tridipole 20, consisting of the the connecting piece connecting the tubular conductor 12 to the inner conductor 10 26, visible.

The further variant of a shown in FIGS. 10, 11 and 12 omnidirectional antenna unit consisting of two nested radiator groups, consists of a group of collinear half-wave dipoles and a slot radiator group, of which each slot radiator 29 out of six evenly distributed around the circumference % / c.-long Långsschlitzen 29 'consists. In contrast to the embodiments according to FIGS. 6 to 9 is here, as the partial longitudinal section according to FIG. 10 shows, in the Middle fed Malbwave dipoles 19 'the inner one from the inner liner 10 and the tubular conductor 12 existing coaxial line of the double coaxial line as a feed line assigned. The slot radiators are made via the outer, tubular conductor 12 and the outer conductor 11 existing coaxial line fed. For compensation the short circuit at the point where the inner coaxial line is passed through to the feed point of the half-wave dipoles 19 'through the outer coaxial line are in place Bushing in the space between the tubular conductor 12 and the outer conductor 11 coaxial A / 4 blocking circuits 23 are arranged. Also, as with the embodiments 6 and 8, the space between the tubular conductor 12 and the outer conductor 11 is filled with a dielectric 24, which at a distance of Seat radiator of 3/4 A o, with the wavelength Ao o in air, for an electric one Line length spacing of c ner wavelength is dimensioned.

As the plan view on FIG. 11 shows, the half-wave dipoles are 191 slotted dipoles, whose webs 28 with respect to the longitudinal slots 29 'of the slot radiator 29 are arranged so that the longitudinal slots 29 'between the webs 28 of the half-wave dipoles 19 'can radiate through.

In this way, a very compact design is made possible in which the half-wave dipoles 19 'and the slot radiators with their longitudinal slots. 29' overlap each other. The longitudinal slots of the slot radiators are excited in the middle through coupling pins protruding into the coaxial line 4.

The indicated in Fig. 11 section B / B 'pins in the area of the coupling 4 is shown in FIG. He makes the strictly rotationally symmetrical structure of the nested radiator groups again clearly and shows that with the given dimensioning of the slotted half-wave dipole 19 'on the one hand and the slot width of the longitudinal slots 29 'of the slot radiators 29 despite the mutual Overlap a practically undisturbed mutual operation of the two omnidirectional antennas performing radiator groups is possible.

19 claims 12 figures

Claims (19)

Claims ff 1. Antenna arrangement, in particular for spacecraft, with a single omnidirectional antenna and a reflector for transforming the characteristics the omnidirectional antenna in a directional characteristic, characterized in that two, having separate feed lines omnidirectional antennas with mutually orthogonal linear polarization to form a rod-shaped structural unit (2, 2 ') are, and that the reflector (6, 6 '; 16, 17, 21) for a polarization-dependent Reflection behavior is designed such that it is practically only for one of the two Omnidirectional antennas are effective. 2. Antenna arrangement according to claim 1, characterized in that the reflector around a coincident with the rod axis of the beam antenna unit (2, 2 ') Axis is rotatably mounted. 3. Antenna arrangement according to claim 1, characterized in that the separate feed line to the two omnidirectional antennas via concentric to each other arranged coaxial lines takes place. 4. Antenna arrangement according to one of the preceding claims, characterized characterized that the one omnidirectional antenna of the omnidirectional antenna unit (2, 2 ') is a rod-shaped linear radiator with the second circular antenna in the center is located. 5. Antenna arrangement according to claim 4, characterized in that the linear radiator is provided with slots (3) and designed as a coaxial line Tube is that merges into a double cone antenna (5) in the center. 6. Antenna arrangement according to claim 4, characterized in that the linear radiator consists of a group of collinear dipoles (13) in which Center a slot radiator (14) is arranged. 7. Antenna arrangement according to one of the preceding claims, characterized characterized in that the reflector (6, 6 '; 16, 17, 21) consists of thin straight or curved metallic strips or bars (22). 8. Antenna arrangement according to claim 5 and 7, characterized in that that the reflector (6, 17) is a parabolic of revolution, in whose focal point the double-cone antenna (5) is arranged, and that here the metallic strips or bars in planes which go through the rod axis of the omnidirectional antenna unit (2). 9, antenna arrangement according to claims 6 and 7, characterized in that that the reflector (6 ', 16) is a parabolic of revolution, and that here the metallic Strips or rods lie in planes which are defined by a perpendicular to the rod axis of the Omnidirectional antenna unit aligned, go the focal point containing axis. 10. Antenna arrangement, in particular according to one of claims 1 to 3, characterized in that the two omnidirectional antennas the end two evenly distributed over the length of the rod-shaped omnidirectional antenna unit and nested radiator groups (19/20, 19 '/ 29) exist and that the separate supply lines for both radiator groups are arranged concentrically to one another. and form a double coaxial line, the axis of symmetry of which with the axis of symmetry the omnidirectional antenna unit (2 ') coincides. 11. Antenna arrangement according to claim 10, characterized in that one radiator group of collinear dipoles (19) and the other radiator group consists of tridipoles (20). 12. Antenna arrangement according to claim 11, characterized in that the tridipoles (20) in the extension of the omnidirectional antenna unit between two successive ones Dipoles (19) are arranged, and that the dipoles of a radiator group to the outer and the tridipoles of the other radiator group to the inner coaxial line the double coaxial line are connected and for this purpose the outer coaxial line is provided with A / 4 blocking circuits (23) in the area of the connections of the tridipole. 13. Antenna arrangement according to claim 11, characterized in that one dipole (19) each - the one emitter group with a tridipole (20) of the other Emitter group is assembled in such a way that the tridipole in He stretching of the dipole and thus the omnidirectional antenna unit (2 ') between the two dipole halves -Is arranged and that the -Dipole -the one radiator group to the outer and the tridipoles.der other radiator group to the inner coaxial line of the double coaxial line are switched on. Antenna arrangement according to Claim 10, characterized in that the one radiator group of collinear dipoles (19 ') and the other radiator group consists of slot radiators (29), of which each slot radiator several on the circumference the omnidirectional antenna unit has evenly distributed longitudinal slots (29 '), and that the dipoles of a group of radiators are connected to the inner and the slot radiators the other radiator group to the outer coaxial line of the double coaxial line are switched on and for this purpose the outer coaxial line in the area of the connections the dipole is provided with ß / 4 blocking circuits (23). 1 antenna arrangement according to claim 14, characterized in that the dipoles (19 ') of one radiator group and the slot radiators (29) of the other Emitter groups overlap each other and that the dipoles are longitudinally slotted dipoles are whose longitudinal slots (29 ') with the slots of the slot radiator to cover are brought. 16. Antenna arrangement according to one of claims 10 to 13, in which the dipoles used are half-wave dipoles, characterized in that the distance between two successive ones in the extension of the omnidirectional antenna unit Half-wave dipoles 3/4 of a wavelength A in air and the electrical length by means of suitable configuration of the outer coaxial line a line wavelength ß amounts to. 17. Antenna arrangement according to claim 14 or 15, wherein the slot radiator Half-wave slot radiators are characterized in that the mechanical distance between the excitation pins of two in the extension of the omnidirectional antenna unit successive slot radiators 3/4 of a wavelength Ao in air and the -electric Distance by means of a suitable design of the outer coaxial line one wavelength ß is. 18. Antenna arrangement. according to claim 7 and one of claims 11 to 18, characterized in that the reflector (22) is a cylindrical parabolic from parallel to the focal line arranged rods (22) or strips is, in the focal line the rod-shaped omnidirectional antenna unit (2 ') is arranged. 19. Antenna arrangement according to one of the preceding claims Reflector, characterized in that one, the primary radiator of the directional antenna performing omnidirectional antenna is provided with an auxiliary reflector (18). L e r s e i t e