DE2007921B2 - Antenna arrangement, consisting of a rod-shaped omnidirectional antenna and a directional antenna - Google Patents

Description

The invention relates to an antenna array, in particular for spacecraft, consisting of from the constructive union of two antennas with separate leads, namely a rod-shaped omnidirectional antenna and a directional antenna, from which the directional antenna extends an omnidirectional radiator as a primary radiator and a reflector as a secondary radiator.

Such a combined antenna arrangement is described, for example, in the German patent 754 839 known. Here, the omnidirectional antenna and the directional antenna are one above the other arranged that the omnidirectional antenna of the directional antenna serves as a mast. The omnidirectional antenna is provided for electromagnetic waves of relatively long wavelengths, while the directional antenna is designed for much shorter electromagnetic waves, as they are in general for Directional radio links are used.

Such combined antenna arrangements are also used in spin stabilized spacecraft required, but here only for very short electromagnetic waves. Such a spacecraft requires an omnidirectional antenna which, in conjunction with a suitable reflector, leads to a Directional antenna is designed. The alignment of the Ricntantenne, a corresponding arrangement of the Assuming an omnidirectional antenna, the reflector moves in opposite directions around the Spin axis of the spacecraft. For this purpose, the reflector is rotatably arranged in a bearing and driven by a tracking motor via suitable control electronics. If the reflector tracking fails, then operation via the directional antenna is no longer possible. Through the USA patent 3 341 151 it is known from blasting off and thus making the reflector ineffective Auxiliary operation is now exercised in an omnidirectional antenna Maintaining converted directional antenna. The blasting off of the reflector brings considerable results Risks with it and also requires bo a considerable mechanical effort. One independent arrangement of the directional antenna and the omnidirectional antenna required for auxiliary operation one above the other in the direction of the spin axis also causes considerable difficulties, because with regard to the available space, the weight. the strength, the cable routing, the thermal Behavior and the moment of inertia are tight limits. Also other separate arrangements the omnidirectional antenna, for example on the opposite side of the spacecraft usually for similar or electrical reasons.

The invention is based on the object for an omnidirectional beam operation and a directional beam operation enabling antenna arrangement to provide a further solution that has a compact structure the overall antenna and in particular as an antenna for spin-stabilized spacecraft application Can be found.

This object is achieved according to the invention in that the omnidirectional antenna and the omnidirectional antenna the directional antenna combined into a rod-shaped unit encompassed by the reflector of the directional antenna are and on the one hand the omnidirectional antenna and the omnidirectional antenna are mutually orthogonal Have linear polarization and on the other hand the reflector for a polarity-dependent Reflection behavior is designed such that it is essentially only the linearly polarized radiation of the Omnidirectional antenna, but not the orthogonal linearly polarized radiation from the omnidirectional antenna reflected.

The invention is based on the knowledge that with the help of two separately fed omnidirectional antennas a compact antenna structure is possible with mutually orthogonal linear polarization the two antennas are electrically decoupled from each other by a suitable design of the reflector can.

When using the antenna arrangement according to the invention for a spin-stabilized space probe it is necessary to move the reflector around a coincident with the rod axis of the rod-shaped unit To store the axis rotatably, because here only by a rotational movement in the opposite direction to the spin direction the reflector a local alignment of the directional antenna is possible.

The compact structure of the antenna arrangement is promoted in a special way when the separate feed lines to the omnidirectional antenna and the omnidirectional antenna are arranged concentrically to one another Coaxial lines are.

In a first basic embodiment according to the invention, the reflector is a parabolic of revolution, in whose focal point is the omnidirectional radiator and the omnidirectional antenna is a rod-shaped linear radiator, in the center of which is the omnidirectional radiator.

The linear radiator can advantageously be provided with slots and configured as a coaxial line Be the tube that for the implementation of the omnidirectional antenna in the center in a double cone antenna transforms.

A further advantageous embodiment sees a group of collinear dipoles as 1 linear radiator before. in the center of which a slot radiator is arranged for realizing the omnidirectional radiator.

Towards a reflector for a polarization-dependent reflection behavior can be easily made into a thin straight or curved metallic strip realizing fencing or rods.

If the omnidirectional antenna is a double-cone antenna, then the metallic ones forming the reflector lie! Strips or rods in plane that go through the rod axis of the slab-shaped unit. 1st de

5 6

Omnidirectional radiators, on the other hand, have a slot antenna, then lie inwards against the vertex. Such a

Against the metallic strips or rods in levels, "deep" reflector brings certain impairments

due to an omnidirectional flow characteristic perpendicular to the rod axis. For some

It is advisable to use cases of application that are aligned with the

going to the tending axis. 5 a "deep" reflector a "flat" reflector

In the case of a second basic embodiment, which is to be provided, and the resulting

the reflector is a cylindrical parabolic, the loss of which has to be compensated for by an auxiliary reflector

Focal line the rod-shaped unit is arranged, sieren.

exist the omnidirectional antenna and also the omnidirectional emitter shown in the drawing From two evenly over the length of the m management examples, the invention is intended in the following rod-shaped unit distributed radiator groups, which will be explained in more detail. In the drawing together are nested. Here are the points for

both radiator groups to separate feed lines. 1 a first exemplary embodiment for an erander arranged concentrically and form a double basic embodiment according to the invention, pelkoaxialleitung, the axis of symmetry with the 15 Fig. 2 a section of the rod-shaped unit Axis of symmetry of the rod-shaped unit together according to FIG. 1, omitted. F i g. 3 a second exemplary embodiment for a

In a first preferred embodiment ste basic embodiment according to the invention, for this second basic embodiment, FIG. 4 shows a third exemplary embodiment for a single Emitter group of collinear dipoles and the 20th basic embodiment according to the invention, other emitter group from tridipoles. F i g. 5 shows a first embodiment for a

The tridipoles are expedient in extension of the second basic embodiment according to the invention,

rod-shaped unit between two successive F i g. 6 a partial section of the rod-shaped unit

arranged opposite collinear dipoles. The colli- according to F i g. 5,

near dipoles are attached to the outer and the tridipoles 25 F i g. 7 is a partial cut-de ^r rod-shaped unit

to the inner coaxial line of the double coaxial line according to Fig. 5,

device switched on, the outer coaxial line F i g. 8 and 9 sections of a second section

in the area of the connections of the tridipoles with /.A- example for a second basic version

Lock circles is provided. shape according to the invention,

Another advantageous possibility is shown in 3 ° FIGS. 10, 11 and 12 of partial sections of a third

therein, each a collinear dipole with a tri-embodiment for a second basic execution

to combine dipnl in such a way that the Tridi- rungsform according to the invention.

pol between the two dipole halves of the co-linear The embodiment according to FIG. 1 shows the Dipole is arranged and here the collinear Di antenna platform 1 of a spin-stabilized space pole to the outer and the tridipoles to the inner 35 probe, which consists of an omnidirectional antenna and Coaxial line of the double coaxial line connected to a round radiator existing round tube antenna are. unit 2 with its rod axis with the spin axis of the

Another preferred embodiment for probe coincides. Operate the omnidirectional antenna The second basic embodiment consists in what looks like a group of one on top of the other Radiator group collinearly arranged dipoles 40 th slot radiators, the longitudinal slots with 3 and and as another group of radiators, slot radiators in front of which the longitudinal slits for radiation-stimulating heads, Of which each slot radiator several are designated with 4 on the pelstifte. The omnidirectional radiators of the The circumference of the rod-shaped unit is a uniformly rod-shaped unit arranged in the middle Has longitudinal slots. In this case, the nete double cone antenna 5, which is in the focal point of the Dipoles to the inner and the slot radiators to the 45 reflector 6 representing a parabolic of revolution Coaxial line of the double coaxial line is arranged. The reflector 6 is with the foot-side switched and this the outer coaxial line in the bracket? in the camp 8 with tracking motor in the Area of the connections of the dipoles with /./4-Sperrkreis- rod axis of the unit and thus in the spin axis provided. the spin-stabilized space probe rotatably mounted.

With an optimal design of the rod-shaped 5 = the tracking motor moves the reflector 6 in the opposite direction

The dipoles and the slot overlap the spin motion of the space probe in the sense of a unit

spotlights each other. In this case, in order to have a fixed spatial orientation that is derived from the

side disturbing influence of the two radiator reflector 6 and the double cone antenna 5 exist-

To switch off groups, the cylinder sleeves point to the directional antenna.

of the dipole longitudinal slots, which with the slots 55 The partial longitudinal section of the rod-shaped Einheil

the slot radiator are brought into congruence. according to FIG. 2 in the area of the double cone antenna c

When building the rod-shaped unit with the help of the separate supply lines or feed lines

two nested radiator groups for the omnidirectional antenna and the omnidirectional antenna

know using a cylinder parabolic. The separate supply lines consist of:

Reflector, the reflector consists of 60 coaxial lines parallel to each other and concentric to one another

Focal line arranged rods or strips. Order, hereinafter referred to as Doppelkoaxialleituni

To get as high a proportion as possible of the radiated is referred to. The one coaxial line with the

th electromagnetic energy of the focal point outer conductor 9 and the inner conductor 10 serves the above

of the rotary parabolic reflector or in the Brennli ren half of the slot radiator group as a supply line

Never the cylinder parabolic reflector arranged 65 while the coaxial line with the outer conductor ΐ

To bundle omnidirectional radiators, it is necessary to and the tubular conductor 12, which in this case in Bc

Design the reflector so that its focal point or the double-cone antenna reaches into the outer conductor!

its focal line in the axis of rotation passes over as far as possible to the first-mentioned coaxial line, the Zulei

tUng for the double cone antenna. The Kohen is whose focal point lies in the aperture plane, axial line with the conductors 11 and 11 'serves as a supply The desired high bundling of the directional antenna guidance to the lower half of the slot radiator group. is here with the help of a spherical auxiliary reflector The omnidirectional antenna and the omnidirectional antenna are reached 18, the one in front of the double cone antenna anfür mutually orthogonal linear polarization is ordered and its direct radiation on the remessen. The direction of polarization of the electrical reflector 17 throws back.

Field E is in the Fi g. 1 for both antennas by In the first embodiment shown in FIG.

indicated by an arrow. According to this, from the example for a second basic embodiment The omnidirectional antenna is implemented for the omnidirectional antenna and a linear horizontal and the double cone anio the omnidirectional radiators each from a group of split a linear vertical polarization. Made use of the spotlights. In the case of the rod-shaped The reflector 6 must therefore, with regard to its unit 2 'according to FIG. 5, have the one beam desired The reflexive behavior should be measured in such a way that a group of colliners is arranged in the axis of the rod he the vertical linear polarization of the double half-wave dipoles 19 and the other radiator cone antenna reflected and for the horizontal group of tridipoles 20. The two radiator groups are near The polarization of the slot radiator group are nested in one another in such a way that in the extension table is ineffective. As already mentioned in the introduction, this is the rod-shaped unit 2 'between has been carried out, achieved in that the me- two half-wave dipoles 19 each one of three mandatory Strips or rods from which the reflective half-wave dipoles consist of a tridipole 20 gate 6 consists, lie in planes, which is arranged by the rod 20. The reflector 21 has here, as well go to the axis of the rod-shaped unit. for the following executions still to be discussed

The in F i g. 3 shown combined directional examples, the shape of a cylindrical parabolic, in a beam-omnidirectional antenna differs from the focal line of which the rod-shaped unit 2 ′ an exemplary embodiment according to FIG. 1 in that it is ordered. The reflector 21 consists of thin rods 22 arranged parallel to the omnidirectional antenna instead of a slot radiator 25 of its focal line Unit 2 'omitted, poles 13, for example half-wave dipoles, consists like the one in FIG. 4 with the embodiment shown in FIG. 4 and a flat rotating parabolic reflector in the center of the rod-shaped unit, it is also an ordered round radiator, a slot radiator 14. The 3 ° possible here to give the cylindrical parabolic reflector a polarization of the electric field E is to be given here an oppositely flat shape and the resulting from the embodiment according to FIG. 1 exchanges greater radiation losses compared to a deep one, namely the slot radiator to be compensated in the center by means of an auxiliary reflector now has a linear horizontal polarization, which in this case, for example, has a linear vertical polarization parallel to the rod-shaped dipole group. 35 unit can be arranged in front of this rod.
This requires the formation of the rods. The two radiator groups are fed,

or strips constructed, represent a parabolic of revolution as well as in the embodiments according to the placing reflector 6 'in such a way that the metal F i g. 1 to 4. via one in the rod axis of the Stabförlische Strips or rods lie in planes, the migen unit 2 'running double coaxial line, by a perpendicular to the rod axis of the rod-shaped 40 The connections for the half-wave dipoles of the one Unit aligned, the focal point containing emitter group on the one hand and the tridipoles of the other axis walk. Ren radiator groups on the other hand are excerpts

In Fig. 3 is shown in broken line on the one hand in F i g. 6 and 7 shown.

one horizontally in the area of the slot radiator 14. 6 shows part of a longitudinal section in FIG

ordered dielectric plate 15 as well as one of the 45 axis direction of the rod-shaped unit 2 'after Rotational parabolic shape deviating reflector 16 an- F i g. 5, where for the sake of simplicity only interpreted. The dielectric plate 15 causes the upper half of the section to be stronger in relation to the axis of symmetry Bundling of the slot radiator 14 and is given. The half-wave dipoles 19 are over this enables a more favorable design of the annular slot 22 in the outer conductor of the Reflector in the sense of a shape that is between 5 ° outer conductor 11 and the tubular conductor 12 as a parabolic parabolic rotation and a parabolic cylinder inner conductor fed existing coaxial line. the lies. The feed points shown in FIGS. 1 and 3 are in the middle of each Embodiment of the reflector 6 or 6 ', in the case of the half-wave dipole 19 consisting of two λ / 4 parts the focal point of the parabolic of revolution is practically provided in. The one between the two half-wave diders Center of the connecting line between vertex 55 poles 19 arranged tridipole 20 stands out with the and reflector opening is located, there will be a good bond between the inner conductor 10 and the tubular conductor 12 delung of the round beam arranged in the focal point of the first-mentioned coaxial line as an outer conductor ir lers achieved, but can with this reflector shape connection. To the short circuit in the derr certain impairments of a contactor outer conductor 11 and the tubular conductor 12 be Radiator or dipole group existing round 60 standing coaxial line at the place of implementation Radiation antenna occur. the inner coaxial line to the tridipole 20 to grain

Another possibility to deviate from the deep rotapensioning, the outer coaxial line in the parabolic shape of the reflector, is in the area of the inner Ko F i g penetrating to the outside. 4 shown. F i g. 4 again shows a round-axial line; ./ 4 locking circuit 23. In order to achieve a possible beam antenna 2 with a doublet arranged in the center 65 high gain for a given length of the rod cone antenna according to FIG of "/ 4 λ _η , mi reflector 17 with a flat parabolic shape of revolution intended for wavelength ?, ₀ in air. To cim

to achieve in-phase feeding of the successive half-wave dipoles at this distance, is the space between the inner and outer conductors of the outer coaxial line with a dielectric 24 filled in such a quality that the wavelength in the coaxial line is just equal to the Is the distance between two successive feed points.

F i g. 7 shows the in FIG. 6 indicated section A-A ', which shows the structure of a tridipole 20 better. The tridipole consists of three in-phase fed curved half-wave dipoles 20 'which are supplemented in a plane to form a circle. Each half-wave dipole 20 'is composed of two A' 4 partial gaps. The feeding points of these half-wave dipoles 20 'are made in the middle, as in the case of the half-wave dipoles 19 according to FIG. 6.

The interleaving of the two radiator groups consisting of half-wave dipoles and tridipoles to form a rod-shaped unit can also take place in such a way that the tridipoles 20 are each arranged between two A ^ sections of a half-wave dipole. A partial sectional drawing corresponding to FIG. 6 for such an embodiment is shown in FIG The connection points of the half-wave dipoles 20 'of the tridipole 20 takes place at the point where the half-wave dipoles 19 are fed, in contrast to the embodiment nf-li FIG. 6 on A ^; 4 trap circles can be eliminated. The connection of the tubular conductor 12 to the right A4 section of the half-wave dipole 19 takes place via the connection piece 25. From FIG. 9, which shows a plan view of the section shown in longitudinal section according to FIG. 8 represents, on the one hand, the feed point for the half-wave dipole 19, consisting of the connecting piece 25 and the tubular conductor 12, as well as the feeding point for one of the half-wave dipoles of the tridipole 20, consisting of the connecting piece 26 connecting the tubular conductor 12 to the inner conductor 10, visible.

The in the Fi g. 10, 11 and 12 another variant of a rod-shaped unit consisting of two nested radiator ribs consists of a group of collinear half-wave dipoles and a slot radiator group, of which each slot radiator 29 consists of six A / 2-long longitudinal slots 29 'evenly distributed around the circumference. In contrast to the embodiments according to FIGS. 6 to 9 is how the partial longitudinal section according to Fi g. 10 shows that the half-wave dipoles 19 'fed in the center are assigned the inner coaxial line consisting of the inner conductor 10 and the tubular conductor 12 of the double coaxial line as a feed line. The slot radiators are fed via the outer coaxial line consisting of the tubular conductor 12 and the outer conductor 11. To compensate for the short circuit at the point where the inner coaxial line passes through to the feed point of the Halbweliendipula 19 'through the outer coaxial line, coaxial A / 4 blocking circuits 23 are arranged at this point in the space between the tubular conductor 12 and the outer conductor 11. Also, as in the embodiments according to FIGS. 6 and f ¹ the space between the tubular I eiler 12 and the outer conductor 11 is filled with a dielectric 24, which at a distance of the slot radiators of ³ 4 A ₀ , with the wavelength A _n in air, for an electrical line length spacing of one white length is measured.

As the plan view of FIG. 11 shows, the Half-wave dipoles 19 'slotted dipoles whose webs 28 with respect to the longitudinal slots 29' of Schlilzstrah-

3c ler 29 are arranged so that the longitudinal slots 29 ' can radiate through between the webs 28 of the half-wave dipoles 19 '. That way becomes a allows a very compact design, in which the half-wave dipoles 19 'and the slot radiator with their longitudinal slots 29 'overlap each other. The excitation of the longitudinal slots of the slot radiator takes place in the middle by coupling pins protruding into the coaxial line 4.

The in F i g. Section BB ' indicated in FIG. 11 in the area of the coupling pins 4 is shown in FIG. It makes the strictly rotationally symmetrical structure of the nested radiator groups clear again and shows that with the given dimensioning of the slotted half-wave diameter

pole 19 'on the one hand and the slot width of the longitudinal slots 29' of the slot radiator 29 despite the mutual Overlap a practically undisturbed mutual operation of the two circular antennas performing radiator groups is possible.

For this purpose 2 sheets of drawings

Claims (19)

Patent claims: 1. Antenna arrangement, especially for Spacecraft, consisting of the constructive union of two antennas with separate Supply lines, namely a rod-shaped omnidirectional antenna and a directional antenna, from which the directional antenna consists of an omnidirectional radiator as a primary radiator and a reflector composed as a secondary radiator, characterized in that the omnidirectional antenna and the omnidirectional antenna of the directional antenna to one of the reflector (6, 6 ', 16, 17, 21) of the directional antenna comprised rod-shaped unit are combined and on the one hand the round beam antenna and the omnidirectional radiator have a mutually orthogonal linear polarization and on the other hand the reflector for a polarity-dependent one Reflection behavior is designed such that it is essentially only the linearly polarized Radiation of the omnidirectional radiator, but not the orthogonal linearly polarized radiation the omnidirectional antenna reflects. 2. Antenna arrangement according to claim 1, characterized in that the reflector is mounted rotatably about an axis coinciding with the rod axis of the rod-shaped unit (2, T). 3. Antenna arrangement according to claim 1, characterized in that the separate leads to the omnidirectional antenna and the omnidirectional antenna arranged concentrically to one another Coaxial lines are. 4. Antenna arrangement according to one of the preceding claims, characterized in that that the reflector (6, 17) is a parabolic of revolution, in whose focal point the omnidirectional radiator (5) is arranged that the omnidirectional antenna is a rod-shaped linear radiator in the center the omnidirectional radiator is located. 5. Antenna arrangement according to claim 4, characterized in that the linear radiator is a is provided with slots (3), designed as a coaxial pipe, which is used to implement the Omnidirectional antenna merges into a double cone antenna (S) in the center. 6. Antenna arrangement according to claim 4, characterized in that the linear radiator from a group of collinear dipoles (13), in the center of which to realize the Omnidirectional radiator a slot radiator (14) is arranged. 7. Antenna arrangement according to one of the preceding claims, characterized in that that the reflector (6, 6 '; 16, 17, 21) consists of thin straight or curved metallic strips or rods (22). 8. Antenna arrangement according to claim 7, which is dependent on claim 5, characterized in that the metallic strips or rods lie in planes which go through the rod axis of the rod-shaped unit (2): ¹ ; 9. Antenna arrangement according to claim 7, which refers back to claim 6, characterized in that that the metallic strips or rods (22) lie in planes which are perpendicular through a t.cnrecht The axis containing the focal point is aligned with the rod axis of the rod-shaped unit walk. 10. Antenna arrangement according to one of claims 1 to 3, characterized in that the The reflector (21) is a cylindrical parabolic, in the focal line of which the rod-shaped unit (2 ') is arranged is, and that the omnidirectional antenna and also the omnidirectional antenna from each one evenly over the length of the rod-shaped unit distributed radiator group (19/20, 19729) exist, the both are nested in one another, and that the feed lines for both radiator groups are separate are arranged concentrically to one another and form a double coaxial line whose axis of symmetry coincides with the axis of symmetry of the rod-shaped unit (2 '). 11. Antenna arrangement according to claim 10, characterized in that the one radiator group consists of collinear dipoles (19) and the other radiator group of tridipoles (20). 12. Antenna arrangement according to claim 11, characterized in that the tridipoles (20) in the extension of the rod-shaped unit between two successive collinear dipoles (19) are arranged and that the collinear dipoles to the outer and the tridipoles to the inner Coaxial line of the double coaxial line are connected and for this purpose the outer coaxial line is provided with /.,4 blocking circuits (23) in the area of the connections of the tridipoles. 13. Antenna arrangement according to claim 11, characterized in that in each case a collinear Dipole (19) with a tridipole (20) is joined together in such a way that the tridipole is between the two dipole halves of the collinear dipole is arranged and that the collinear dipoles connected to the outer and the tridipoles to the inner coaxial line of the double coaxial line are. 14. Antenna arrangement according to claim in. characterized in that one radiator group consists of collinear dipoles (19 ') and the other Radiator group consists of slot radiators (29), each of which has several slot radiators The circumference of the rod-shaped unit has uniformly distributed longitudinal slots (29 '), and that the Dipoles on the inner and the slot radiators on the outer coaxial line of the double coaxial line are switched on and that the outer coaxial line in the area of the connections of the dipoles is provided with /.4 blocking circuits (23). 15. Antenna arrangement according to claim 14, characterized in that the dipoles (19 ') and the final radiators (29) overlap one another and that the cylinder sleeves of the dipoles Have longitudinal slots (29 ') which are brought into congruence with the slots of the slot radiator are. 16. Antenna arrangement according to one of claims 11 to 13, wherein the collinear half wave dipoles dipoles are used, characterized in that the distance between two in the extension of the rod-shaped unit consecutive half-wave ^{dipoles; i} / ₄ of a length WEI in air and the electrical length by means of a suitable configuration of the outer coaxial line, the length / length of the line is. 17. Antenna arrangement according to claim 14 or 15, in which the longitudinal slots are half-wave slots are, characterized in that the mechanical distance between the centers of two successive slots V _{4 of} one wavelength in the extension of the omnidirectional antenna unit). _o in air and the electrical distance by means of a suitable design of the outer b coaxial line is a wavelength /. 18. Antenna arrangement according to one of claims 10 to 17, characterized in that the reflector (22) consists of rods (22) or strips arranged parallel to the focal line. 19. Antenna arrangement according to one of the preceding claims, characterized in that that the omnidirectional radiator is provided with an auxiliary reflector (18). 15th