DE1912565A1 - Radio antenna with directional beam - Google Patents

Description

PATENT LAWYERS IZODQ H. LEINWEBER difl- ing. H. ZIMMERMANN

• Mündiea 2, Rosental 7. z.Auig.

ΤβΙ.-addr. IeI phone

March 12, 1969

Our sign

Z / Va / Wy / Lo

COMPAGNIE GENERALE D ¹ ELECTRICITe, Paris (France) Radio antenna with directional beam

The invention relates to a radio antenna with directional radiation lobe, namely a very large antenna that a large, essentially spherical shell-shaped reflector having. Such a reflector can have a diameter of the order of magnitude of, for example, approximately one hundred meters. In particular, it must be non-deformable due to the action of wind and therefore relatively heavy. It is it takes a lot of effort to build it straightenable. Such antennas are particularly intended for systems that connect to Manufacture artificial satellites for the purpose of long-distance transmissions have been put into orbit around the earth. However, such satellites are difficult to relate to be held stationary to earth. The lobe of antenna radiation with maximum power or reception with maximum The sensitivity of the antenna must therefore be adjustable

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the angular space for the directional movement at least some Must be degrees. Such directability of the radiation lobe in relation to the axis of the antenna with a small angular space on the order of a few degrees is also desirable if the antenna itself can be directional. Precise alignment of a large diameter antenna is difficult and expensive. It is therefore necessary after Rough adjustment of the antenna in one direction by acting on a small component of the antenna, for example the emission source or a small reflector to swivel the club.

It is known to locate the large reflector in relation to earth and when using the antenna as a transmitter will, by means of a small one, near its focal area arranged reflector to irradiate. If, as is generally the case, the radiation source or the radiation head is to be regarded as point-shaped, the shape of the small one becomes Reflector chosen so that the radiation point such a conjugate point to a point of the focal area of the large Reflector is that the waves received by the large reflector diverge from this point and that, as a result, that the beam emitted by the large reflector is substantially parallel. With an adjustable large reflector It is possible, starting from a point-shaped radiation head, to achieve an absolutely precise parallelism of the emitted beam to achieve (if one does not neglect calculation phenomena). It is enough to give the large reflector the shape of a Paraboloids of revolution and the small reflector the shape

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an ellipsoid or hyperboloid of revolution, where one of the two focal points of the small reflector is on the radiation head, while the other is the both focal points coincides with the focal point of the large reflector. This favorable situation cannot persist when the direction of the emitted beam is changed with respect to the axis of the large reflector must become. This must therefore not only have a focal point, but must have a focal area in which everyone Point must play the role of a focal point for a certain orientation of the beam. The little reflector is then used to place the rays on the point of the focal point area corresponding to the direction of emission to collect. The position of the small reflector must therefore be changed depending on the point concerned can. Under these conditions, the stigmatism of the optical system thus constructed, i.e. practically the Parallelism of the emitted beam can only be achieved approximately. To improve them it is known to give the large reflector a shape deviating from the paraboloid and approaching a spherical shell, while the small reflector is given a more or less complex shape, which is intended to extend as much as possible the to compensate for aberrations caused by the large reflector. To this compensation, i.e. the parallelism of the delivered The best way to ensure the bundle of rays does not only have to depend on the position and direction of the small reflector of the desired direction of the emitted jet

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lenbündels, but also its shape can be adjusted. Such an adaptation of the shape of the small reflector requires necessarily complicated mechanics and thus increased costs. Even if the shape of the small reflector isn't too change, on the other hand, requires the alignment of its position and its direction in order to reduce aberration errors, while at the same time ensuring that for the beam desired direction complicated calculations and in practice the use of an automatic computer system.

The disadvantages described appear in the same way when using the antenna as a transmitter and as a receiver, in both cases the problem arises, a broad, parallel bundle of rays of plane radio-electric waves to adapt a bundle of rays of spherical waves, which in a radiation or receiving organ, here referred to as a head, are centered, whereby in practice the head often consists of a horn that connects the transmitter or Receiver manufactures. The difficulties mentioned concern

on the other hand, also the type of structure used: antennas ι

of the type in question are under the name "Cassegrain-

Antennas "known if the small reflector between the large reflector and its focal area is arranged,! and under the name "Gregoriennes-Antennen" if the little one j Reflector beyond the focal area of the large reflector! is provided. The difficulties also show up when

ι a radio-electric lens instead of the small reflector

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is used, which gives the waves passing through them variable phase shifts.

The invention is intended to remedy the disadvantages and difficulties mentioned.

The radio antenna according to the invention with a directional radiation lobe has a large, stationary one in a known manner Reflector in the form of a spherical shell and an optical transmission system that the radio waves from the large Reflector directs to a head or vice versa. This head consists of a transmitter for the radio waves if the antenna is used as a transmitting antenna. It consists of a receiver when the antenna works as a receiving antenna. That optical transmission system is movable with respect to the large reflector in such a way that the alignment of the radiation lobe is determined by the position of the optical system. The antenna according to the invention is characterized in that the optical transmission system is rotatable around the center of curvature of the large reflector and that it is able to Bring center of curvature with a point of the focal surface of the large reflector in agreement. Further Means are provided by which the waves which the head emits or to which the head responds, spherical wave surfaces obtained, which are centered in said center of curvature.

The advantages of these arrangements result from a consideration of the geometric figure, for example when sending, through the small and the large reflector and the incident on these reflectors and reflected by them

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tied waves that are formed ". If you look through the edges of the beam irradiating the small reflector and caused by those of the small and large reflectors If limit values are disregarded, it can be seen that this geometric figure is always the same according to the invention remains even if the small reflector is pivoted.

As a result, if the shape of the small reflector is determined so that the aberration errors these aberration errors are reduced to a minimum for a certain direction of the emitted beam at each direction chosen for the emitted beam and at each corresponding position of the small one Reflector are reduced to a minimum.

Further details, advantages and features of the invention emerge from the following description. On the Drawing illustrates the invention by way of example, namely show

1 and 2 schematically and in section a first embodiment; management form of the antenna according to the invention,

! Fig. 3 is a perspective view of the device for Pivoting the auxiliary reflector in two mutually perpendicular directions,

4 and 5 schematically show other embodiments of the antenna according to the invention and

6 and 7 schematically show the position of the edges of the beam of the radio waves with the radiation path parallel to the axis of the large reflector or with Deviate from this axis.

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1 and 2 show an embodiment which, in a known manner, has a large spherical shell-shaped reflector 1 which has a center of curvature 0 and into which a horn 2 opens which is connected to the reflector by a surface. According to the invention, this surface 3 is geometrically part of an ellipse, one focal point of which coincides with the center of curvature 0 of the large reflector and the other focal point F is on the geometric axis zz ^{1 of} the horn, preferably at the tip of the latter.

A small reflector 4 is preferably essentially in the middle between the surface 3 and the center of curvature 0, the antenna shown in FIG. 1 being a Gregorian type antenna acts.

FIG. 2 shows the structure of the antenna shown in FIG. 1 more fully. In this figure the small reflector 4 is held by a hinge 5 which is connected by arms 6, 6 ¹ to a box 7 which is attached to the large reflector 1 ^{by struts 8, 8 1.}

The side of the box facing the reflectors is inclined by 45 ° to the axis of the reflector 1 and the surface of this Side is larger than that of the small reflector 4, so that the parasitic part of the elliptical surface 3 beam emitted on the reflector 4, i.e. the part which laterally passes the latter into the least disturbing direction, namely 90 ° to the direction of the main radiation lobe is sent.

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In an antenna constructed in this way and used for transmission, a radiation source 2 ^{1 is} connected to the tip of the horn 2 and the elliptical surface 3 of the horn emits a wave which converges towards the center of curvature 0 of the large reflector, whereby the "Phase surfaces" of this wave are consequently spherical waves which are centered on the said center of curvature. Under these conditions causes a pivoting of the small ^; nen reflector 4 at a certain angle around this center point a pivoting of the antenna emitted by the antenna radiation beam with the same angular value and the same direction.

Fig. 3 shows a device for pivoting the auxiliary reflector in two mutually perpendicular directions.

In this device, two plates 12 and 13 cooperate through cylindrical surfaces in such a way that they pivot allow in direction χ, while the plate 13 and> a base plate 14 also cooperate by "ylindrische surfaces, which are aligned so that they allow pivoting in direction y perpendicular to direction ζ. By combining these two movements, the reflector 4 can be moved in a spherical surface, with its center point coincides with the center of curvature 0 of the large reflector.

Fig. 4 shows an embodiment in which the horn in the axis of the large reflector 1 on its convex Side arranged and a radioelectric lens 15 on the Connection point between the horn and reflector is attached, whereby a centered on the center of curvature 0 of the large reflector wave is achieved.

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Fig. 5 illustrates an embodiment in which a horn 16 or other classic primary wave source, for example a YAGI antenna, arranged in the center of the large reflector 1 and towards this. aligned and a dielectric or metallic lens 17 about halfway between the horn 16 and the large reflector 1 is arranged. In this case, the waves are also on the center of curvature 0 of the large when receiving Centered reflector, but diverge when transmitting.

The device according to FIG. 3 can be used to pivot the lens 17 carried by an arm to prevent one of the plates of the device from being in its radiation field. The pivoting of the lens around the center of curvature 0 of the large reflector causes the wave bundle transmitted by the antenna to pivot with the same angular value and in the same direction. It is also advantageous to have the horn 16 about the center of curvature 0 to pivot so that the beam emanating from it remains centered on the lens 17.

In Fig. 1 are the boundaries of the street bundle of radio waves not specified.

FIGS. 6 and 7, which correspond to FIG. 1, show the location of these boundaries when the antenna transmitted The bundle of rays should be parallel to the axis of the large reflector or if the bundle of rays from this Axis should deviate.

These figures show a horn radiator 20 which can be pivoted about point F. This horn radiator irradiates

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depending on its orientation an outer part of the elliptical Surface 3. This alignment is coupled to the position of the small reflector 4 by means not shown in such a way that that the bundle of rays directed from the elliptical surface 3 to the small reflector 4 is always centered on this reflector is. On the other hand, the inside width of the beam emitted by the horn 20 is such that the width of the small reflector 4 irradiating beam is substantially equal to the width of this reflector. This one focuses the bundle of rays at a point of the focal surface 22 of the large reflector 1. This focal surface is part a spherical surface with the center 0 and a radius that is half the radius of the sphere of which the large one Reflector 1 represents a spherical cap.

The beam then diverges from this point on the focal surface and reaches the large reflector 1 where it creates a parallel transmit beam. The direction of this transmission beam runs parallel to the straight line which connects the center of curvature 0 with the center of the small reflector 4.

This arrangement on the one hand the transmission power of the horn 20 and on the other hand the surface of the small Best used reflector 4. As far as the area of the large reflector 1 is concerned, it is only ever partial recovered. However, it is possible to reduce this area to such an extent that it is always fully utilized. In this case a part of the transmission power of the horn antenna 20 is lost if the transmission direction is from the axis of the large reflector 1 deviates.

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Claims (3)

Patent claims: MJ radio antenna with directional beam, with a large reflector in the form of a spherical cap and an optical transmission system through which the radio waves pass, which is placed in the radiation path between the large reflector and a head that sends these waves when the antenna is used as a transmitting antenna, or who receives it when the antenna is used as a receiving antenna, the optical transmission system with respect to the large reflector movable and its relative position the alignment of the radiation lobe is determined, characterized in that the optical transmission system (4, 15, 17) around the center of curvature (0) of the large reflector (1) is pivotable that the center of curvature through the optical transmission system (0) and a point of the focal surface (22) of the large reflector (1) are made converged points and that means (3) are provided through which the waves emitted or to be received by the head (2) can be designed as spherical waves, which are centered in the center of curvature (0) of the large reflector. 2. Antenna according to claim 1, wherein the optical transmission system consists of a small reflector in the Close to the focal point of the large reflector, with the head on the opposite side from the small reflector the spherical cap of the large reflector is arranged and the large reflector in the radiation path of the waves between the head and the small reflector is pierced by an opening, -12-009840 / 0599 characterized in that for reflecting the waves between the head (2) and the small reflector (4) with the large reflector (1) permanently connected elliptical reflector (3) is provided which is in the shape of part of an elongated Has an ellipse of revolution, one of which has a focal point at the center of curvature (0) of the large reflector (1) and the other focal point (F) of which is at a point on the head (2), from which the waves emitted by the head emanate or where the waves to be received by the head collect. 3. Antenna according to claim 2, characterized in that the head (2) around the second focal point (F) with respect to, large reflector (1) can be aligned and that the alignment of the head with the position of the small reflector (4) is connected that the from the head (2) emitted or from him to be received wave bundle always on practically the entire usable area of the small reflector (4) and only reflectable on this usable area, the areas of the The opening and the elliptical reflector (3) are large enough that when the reflector (4) and the head (2) are pivoted the beam is never obstructed by the boundaries of the opening or the elliptical reflector. 009840/0599 Blank page