DE8804399U1 - Antenna device - Google Patents

Description

ANTENNA DEVICE

The present invention relates to an antenna device for transmitting and receiving high-frequency electromagnetic radiation with a bundling device for the electromagnetic radiation in the form of a reflector or lens device according to the preamble of claim 1·

So-called reflector antennas or lens antennas are used in particular in the range around and above one GHz. The bundling device in the form of a reflector or a dielectric lens focuses incoming high-frequency electromagnetic radiation on a focal point or electromagnetic radiation emanating from this focal point is directed in the preferred direction.
radiated·! ie such antennas have a directional characteristic as L--de antennas·

For example, EP-A-O D73 511 discloses a reception

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antenna with parabolic reflector for electromagnetic fields from satellites. Geostationary satellites are used both for transmitting telephone connections and, more recently , for transmitting radio and television programs. The associated receiving antennas according to the subject matter of EP-AO 073 511 are therefore aligned on the earth's surface towards the corresponding satellite. The parabolic mirror focuses the extremely weak signal from the satellites onto the receiving part arranged at the focal point of the parabolic mirror . The receiving part is positioned at the focal point of the parabolic mirror using the thinnest possible rod and the receiving part itself is designed to be as small as possible. so that only a very small part of the parabolic mirror is shaded by the fastening device and the receiving part itself* Since in the frequency range in question around and above a GKz the radiated or receivable carrier frequency depends essentially on the geometry of the receiving part or the exciter&igr; only a certain carrier frequency range can be received with such a parabolic antenna* This of course limits the number of channels that can be transmitted or received. Therefore, if an existing parabolic

SS antenna is to be used to receive another geostationary satellite with a different frequency range, the receiving part arranged at the focal point must be replaced in any case* Depending on the size of the distance between the new geostationary satellite and the other, the parabolic mirror may also have to be realigned to the new geostationary satellite* Alternatively, a number of receiving antennas could of course be used which are aligned or set up to the respective satellites* However, such a solution is very expensive and is therefore not suitable for the reception of long-distance

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TV programs via satellite are hardly an option. An analogue problem naturally also arises in the case of transmitting antennas.

The object of the present invention is to develop an antenna device according to the preamble of the claim in such a way that a plurality of carrier frequencies around and above 1 GH; can be received or transmitted with a single antenna.

This problem is solved by the features of claim 1·

According to a preferred embodiment, a parabolic reflector is used as the bundling device, since this achieves a very high antenna efficiency and at the same time the manufacture of parabolic reflectors is comparatively simple. In an advantageous manner, double reflectors can also be used. Double reflectors, for example in the style of the Cassegrain antenna or the Gregory antenna, use a main and an auxiliary reflector. In the case of a receiving antenna, the electromagnetic radiation incident on the main reflector is thrown onto the auxiliary reflector and focused by it through an opening in the main reflector onto a focal point behind the main reflector. This embodiment has the advantage that no restrictions are imposed on the structure of the magazine arrangement with regard to the desirable minimum possible shading (claim 3).

According to an advantageous variant of the present invention, the megazine device has the shape of a thin disk in the edge region of which the individual focal elements are arranged radially. The ma-

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magazine device is connected to the fastening device in such a way that the axis of rotation of the disk-shaped magazine arrangement is perpendicular to the incoming or outgoing electromagnetic radiation. The dimensions of the suspension and the fastening device are selected in such a way that the radial edge of the disk-shaped magazine device is located at the focal point of the bundling device. By rotating the magazine device and its axis of rotation, all the

ID magazine device, position the focal elements one after the other in the focal point of the bundling device. The diameter of the disk-shaped magazine device is essentially determined by the number of focal elements. The magazine device can be equipped with a maximum of 6. The arrangement of the magazine device from the axis of rotation perpendicular to the direction of incidence of the electromagnetic radiation ensures that the bundling device is shadowed as little as possible by the magazine device.

SD achieved (claim 4).

According to an advantageous development of this embodiment, the suspension between the magazine device and the fastening device is rotatably mounted on the fastening device. In this way, the focal element located at the focal point can be aligned according to the polarization direction of the incident radiation. If the present invention is designed as a receiving antenna, this has the following particular advantage. Since the geostationary satellites can only radiate one frequency range with a transmitting antenna, the carrier frequencies are radiated in two mutually perpendicular polarization directions in order to be able to transmit a larger number of channels. By simply rotating the disk-shaped magazine device, the focal element located at the focal point can be aligned according to the polarization direction of the incident radiation.

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sensitive focal element to the desired polarization plane (claim S)

According to a further variant, the magazine device has the shape of a spoked wheel with a hub or a rotation axis, whereby the individual focal elements are arranged at the ends of the spokes facing away from the hub. Two fundamentally different orientations of the magazine arrangement to the bundling device can be realized here. In one case, as in the previously described embodiments with the disk-shaped magazine device, the rotation axis or the hub of the magazine arrangement is oriented perpendicular to the direction of incidence of the received electromagnetic radiation. With regard to the dimensioning and positioning of the fastening device, the same applies here as in the previously described embodiments.

SO The embodiment with a spoked wheel-shaped magazine device can, however, also be designed in such a way that the axis of rotation of the spoked wheel-shaped magazine device is arranged parallel to the direction of incidence of the radiation. In this variant, it is advantageous

2E arrange the entire fastening device outside the area of incidence of the electromagnetic radiation so that no shading occurs due to the fastening device. The switching off is only carried out by the individual spokes that reach into the area of incidence of the radiation with the focal elements located on them. The cup elements on the ends of the individual spokes must therefore be arranged perpendicular to the radial direction (claim b)

j 35 According to an advantageous development of the invention

is the bundling device and the magazine device

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% connected to each other via a common fastening device* This has the advantage that when the bundling device is readjusted, the magazine device is automatically adjusted as well, i.e. that the relative

S Position between bundling device and magazine device remains the same· (claim 7)

In conventional antennas with parabolic reflectors, the fastening device for the rear element usually consists of three supports which are fastened to the edge of the parabolic reflector and are brought together at the focal point of the parabolic reflector. The focal element is fastened at the ridge point of these three support elements and thus at the focal point of the parabolic reflector. This type of fastening device can also be used advantageously for the present invention in a slightly modified form. The modification or difference to the conventional fastening device is that the ridge point of the individual support elements

ED is no longer in the focal point of the parabolic reflector but is at a greater distance from the parabolic reflector than the focal point. The distance between the ridge point and the parabolic reflector is chosen in such a way that, for a given magazine device and a given suspension, the radial edge of the magazine device comes to lie in the focal point. (claim &bgr;)

In an advantageous development of the invention, the common fastening device is rigidly connected to a 3D adjustment device. This makes it possible to automatically adjust the antenna according to the invention to another satellite using a corresponding actuator. (Claim 10)

BS especially for reflectors with larger diameter

In conventional antenna devices, the so-called "*

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The so-called offset effect of radiation incident at different angles is used. This effect consists in the fact that radiation incident at different angles is focused at separation points that are offset from one another. This means that several geostationary satellites located far apart from one another can be received with a single reflector or with a single bundling device. If the possible solutions for the satellites are projected onto the «ff-

ID level of a rigidly connected to the earth's surface

Parabolic reflector! Depending on the geographical latitude of the location of the parabolic antenna, a more or less strongly curved elliptical line is created on which the different focal points of the radiation from the different satellites lie.

This offset effect is used in a further advantageous development of the present invention with a spoked wheel-shaped fiamage device.

BO the spokes have different lengths or the focal elements attached to the spokes can be attached to the spokes at different heights. By using the offset effect, a number of geostationary satellites can be received simultaneously if the antenna device is rigidly connected to the ground or if the antenna device has no adjustment device.

By using spokes of different lengths or by arranging the focal elements on the spokes at different heights, the vertical elements can be positioned at the different focal points of the different satellites. The same effect can be achieved by using spokes of the same length with focal elements at the ends - but the axis of rotation of the spoked wheel conveyor is

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« magazine device is positioned at an angle to the optical axis of the bundling device. The inclination of the axis allows the projection of the edge of the spoked wheel-shaped magazine device onto the opening

S plane of the bundling device is elliptical. This allows the individual focal elements to be positioned at the different focal points by rotating the magazine device. (claim 11 and IS)

According to an advantageous development of the invention, the focal elements located in the magazine device can be rotated about their radial axis and consequently aligned according to the polarization direction of the incident radiation or the polarization direction of the emitted radiation can be adjusted· (claim 13)

Since frequencies in the GHz range are subject to considerable line losses when transmitted via waveguide or coaxial cable,

In known antenna arrangements, the receiving part and a so-called down-converter are integrated into one component and arranged at the focal point of the bundling device. The so-called down-converter transforms the high received frequencies to low

ES lower frequencies! in order to reduce line losses. Such combined focal elements with integrated receiver and down converter are used according to an advantageous development of the invention. (claim IS)

According to an advantageous development of the invention, a high-frequency relay is provided in the magazine device, which connects only that focal element with a signal output or a signal supply line, which is positioned in the focal point of the bundling device. In this way, it is prevented that for each of the

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a separate supply or drainage line is required« (claim

According to a further advantageous development of the invention, a radio or television waveband

\ working transmitter and/or receiver provided· Hit

This advantageous development makes it possible to feed the television programs received by the antenna device into conventional television antennas. In this way, it is possible, for example, to cover a larger area - for example, a residential area - with a single antenna device. In analogue mode, a number of radio stations can of course also access a single antenna in GHz range (claim 17)

In a further advantageous development, the transmitter and/or the receiver are housed in the magazine device SD. In this way, a supply line or discharge line in the form of coaxial cables is completely avoided. It is only necessary to ensure that this receiver and/or transmitter is not shaded by the bundling device (claim lö) SS

According to an advantageous development of the invention, a servomotor is provided on the gas device, which is controlled by a control device. The desired fecal element can be easily moved to this position.

!' 30 example of a control unit located in the house ' select and adjust and also with regard to the position

■■ larization level· By appropriately designing the control unit, programs from different satellites can be set on a television set at the touch of a button, just ^like a conventional television set· (claim

In order to protect the antenna device or at least the focal elements from environmental influences, at least the transmitting or receiving opening of the focal elements is covered with a protective cover that essentially does not affect high-frequency radiation (claim 21)

The various (further developments of the invention all relate to the application of the present invention to receiving antennas. An analogous description of the application of the invention for the case of transmitting antennas is superfluous since in this case only the beam path of the electromagnetic radiation has to be reversed and the focal elements have an exciter or a transmitter for high-frequency electromagnetic radiation in the GHz range instead of a receiving part and down converter.

It is also particularly advantageous that, by using a plurality of focal elements with one and the same transmitter reflector in the satellite, signals modulated using different methods can be transmitted. With appropriate positioning of such a geostationary satellite and taking into account the rotation of the earth, it is possible, for example , to transmit television programs using a modulation method such as that used in the Soviet Union during a certain period of time, while at other times television programs using modulation are transmitted.

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processes such as those used in most of Europe. In this way, a geostationary satellite can be used much more efficiently.

Further details! Features and advantages of the present invention emerge from the following description of several embodiments based on the drawing.

It shows:

Fig. I is a perspective view of a first embodiment of the present invention··

Fig· 5 the embodiment of Fig· I with rotated magazine device·

Fig· 3 is a schematic representation of a second embodiment of the present invention! SO

Fig. 1 is a schematic representation of another embodiment of the present invention!

Fig· 5 is a schematic representation of a fourth embodiment of the present invention and

Fig· b a detail of the embodiment of Fig· 5·

Fig. 1 and Fig. 5 show a first embodiment of the present invention. The antenna device according to the invention has a bundling device in the form of a parabolic reflector 2. A disk-shaped magazine device Is is attached to the parabolic reflector 3 via a fastening device M. The disk-shaped magazine arrangement b is equipped with a plurality of focal elements fl which are arranged on the edge of the

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disk-shaped magazine device in the radial direction The axis of rotation 10 of the magazine device b is oriented perpendicular to the direction of incidence IS of received electromagnetic signals The focal elements β located in the magazine device b each consist of the actual receiving part and a downstream Doun converteri which transforms the received high-frequency radiation in the GHz range to lower frequencies.

The fastening device ¹ I consists of three support elements 14 and a suspension It. The three support elements It are attached to the parabolic reflector S at the same distance from each other and extend from the

Parabolic reflector away against the direction of incidence 13

and meet at a common ridge point SO. In the common ridge point 50, the suspension Ib with the magazine device b located thereon is rotatably mounted. The

SO connecting element and thus the magazine device b located thereon can rotate about an axis parallel to the direction of incidence IS. The magazine arrangement can be rotated via a second servomotor SM which is mounted directly on the axis of rotation 10 of the magazine device b.

SS rotate the axis of rotation 10· The support elements IHt the

Suspension Ils and the disk-shaped magazine arrangement b are dimensioned and positioned in such a way that the radial edge of the disk-shaped magazine arrangement b is located at the focal point Sb of the parabolic reflector S. In this way it is achieved that, depending on the rotational position of the magazine device b, each of the focal elements fi can be positioned at the focal point Sb.

The parabolic reflector S is attached to a stand la so that it can be pivoted both vertically and horizontally.

2fl the parabolic reflector S can be aligned to the coordinates of the desired geostationary satellite·

The radiation emitted by a geostationary satellite is focused by the parabolic reflector 2 into the focal point EL· and thus onto a focal element ß located at the focal point. The received high-frequency signal is converted by the associated down-converter to a corresponding signal with a lower

Frequency transformed· This transformed signal

is sent to a coaxial cable 30 via a high frequency relay (not shown)* The coaxial cable 30 leads the transformed signal to a small television transmitter device 3B - via this small television transmitter device with a transmitting antenna 31 the received signal can be transmitted to a conventional television antenna. Depending on the transmission characteristics of the transmitter antenna 3t, the received signal can be transmitted within a certain radius of the transmitter antenna.

Received SO or only in a certain direction·

Alternatively, the coaxial cable 30 can also be connected directly to the antenna input of a television set (not shown) via the cable 30 or

2£ via an additional cable, appropriate control signals can be fed from a control device (not shown) to both the servomotors 25 and 2M as well as to the adjustment device 2fi*. If the control device is located near the television set, a different channel of a television satellite can be set just as easily as another program on a conventional television set.

Fig. 3 shows a schematic representation of another embodiment of the present invention. This second embodiment also has a parabolic

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flektor MQi a fastening device HS-» a magazine device 1Mi servomotors Mb and MA as well as an adjustment device £0 on· The fastening device consists of a stand device S3i a support beam SM as well as a suspension 5b· The functionality and essentially also the arrangement of the individual parts corresponds to the embodiment according to Fig· 1· Only the design of the fastening device HE is different!i·

An advantage of this embodiment is that, in comparison to the embodiment according to Fig. 1 and 5, a smaller part of the receiving surface of the parabolic reflector E is shaded.

In Fig. M a third embodiment of the present invention is shown schematically. In this third embodiment, a double reflector in the form of a so-called Cassegrain antenna is used. A

EO Cassegrain double reflector has a parabolic

Main reflector bO and a hyperbolic auxiliary reflector b2 arranged at a distance therefrom. The two reflectors are kept at a distance by spacer elements ti. The relative positioning of the main and auxiliary reflectors to one another is such that high-frequency radiation captured by the main reflector bO is reflected onto the auxiliary reflector LiE and is focused by this through an opening t>t> in the main reflector bO onto a focal point h& lying behind the main reflector. A magazine device 70 is positioned in this focal point in a similar manner to the two previous embodiments. All other parts such as fastening device, focal elements etc. correspond to the previous embodiments and are not shown in more detail.

A fourth embodiment will now be explained with reference to Figs. S and b. The fourth embodiment also has a parabolic reflector ACh, a fastening device AS* and a magazine arrangement AH . In contrast to the previous embodiments, no adjustment device is provided - ie the parabolic reflector is rigidly connected to the earth's surface via the fastening device AH. The magazine device AM has a hub 5a, 5b, 5c, 5d, 5e and 5f. The spokes AA to 15 extend in the radial direction from the hub or, if necessary, as can be seen from Fig. b - at an acute angle to the radial direction. The hub fib or the axis of rotation of the magazine device fib is parallel to the beam.

IS direction of the parabolic reflector flO aligned·

The rotational axis of the magazine device AM is rigidly connected to the parabolic reflector AD via a fastening device (not shown in detail). The fastening device and the spokes AA to 15 are dimensioned in such a way that the focal elements located at the ends of the spokes of different lengths can be positioned at different focal points IMi 15i 11b and 17. These different focal points arise from electromagnetic radiation incident at different angles, which is consequently focused by the parabolic reflector onto the focal points IMi 15i ^11b and 17 which are offset from one another.

The use of this so-called offset effect is

particularly advantageous when using large-area parabolic reflectors AO since large-area parabolic reflectors^ are exposed to greater environmental stress and consequently stable positioning is easier to achieve than variable positioning using an adjustment device.

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The various embodiments of the invention all relate to the application of the present invention to receiving antennas. An analogous description of the application of the invention to the case of transmitting antennas is superfluous since in this case only the beam path of the electromagnetic radiation has to be reversed and the focal elements instead of receiving part and transmitter for high-frequency electromagnetic radiation in the GHz range have.

Antennas according to the present invention can be used particularly advantageously in the geostationary satellite mentioned above as transmitting and/or receiving antennas, since in this way a plurality of carrier frequencies can be emitted with a single reflector. It is also particularly advantageous here that by using a plurality of focal elements with one and the same transmitting reflector in the satellite, signals modulated using different methods can be emitted. With appropriate positioning of such a geostationary satellite and taking into account the rotation of the earth,

SS can thus achieve, for example, that during a certain period of time television programs can be transmitted using a modulation method such as that used in the Soviet Union, while at other times television programs can be transmitted using modulation methods such as those used in Western Europe. In this way, a geostationary satellite can be used much more efficiently.

Claims (1)

l.^Antenna device^for high-frequency electromagnetic radiation, in particular in the GHz range, with a bundling device in the form of a reflector or a lens device and at least one focal element in the form of an exciter or a receiver of high-frequency electromagnetic radiation·· wherein the focal element is arranged by means of a fastening device at the focal point of incident electromagnetic radiation i IS characterized·! that a magazine device Cb* 4M* 70* fl4) is equipped with SQ a plurality of focal elements (fl) and 12.DO.nfifl "j * '/· . j V*aaspCs2£lQ5135nS ' that the magazine arrangement is rotatably attached to the fastening device (Hi HSi flH) in such a way that by rotating the magazine device a single one of the focal elements can be positioned at the focal point (Sbi bfli IH-, 15i ¹ Ib-I 1?) of incident electromagnetic radiation* S-antenna device according to claim Ii characterized shows that the bundling device is a parabolic reflector (Si 4Dn bOi ÖD)· 3· Antenna device according to claim 1, characterized in that the bundling device is a double reflector (bOi bS). H- Antenna device according to one of the preceding Claims characterized in that the magazine device (bi HHi 7Oi BH) is a thin disk, in the radial edge area of which the majority of the focal elements (β) are arranged radially, the axis of rotation (1C% flb) of which is arranged perpendicular to the incoming or outgoing electromagnetic radiation (IS) and that the magazine device is attached to the fastening device via a suspension (Ibi Sb). SS direction (5i HOi bOi fiO). 5· Antenna device according to claim Hi, characterized in that the suspension (Ib^ Sb) is arranged rotatably on the fastening device (Si HDi bOi fiO) so that the axis of rotation (lOi fib) of the disk-shaped magazine device (bi HHV 70V) can be rotated perpendicular to the direction (IS) of the incoming or outgoing electromagnetic radiation. b· Antenna device according to one of claims 1 to 3, characterized in that the magazine device (M IM* 704 flM) has a large number of spokes (AAi Ali IQi 1Ii IS) arranged on a hub (Ab)·! at the ends of which facing away from the hub the individual focal elements (A) are arranged· ?. Antenna device according to one of the preceding claims, characterized in that the opening device (S'-, MOi bOi AD) and the magazine device (bi MMi 7Oi AM) are connected to one another via the common fastening device (Mi MSi AS). fl. Antenna device according to one of claims 5 to 7, characterized in that the fastening device (Mi MSi AS) has a plurality of carrier elements (IM) which extend away from the edge of the parabolic reflector (Si MOi hü'-, AO) and SO whose ends facing away from the parabolic reflector are brought together in a ridge point (SO)i whereby the suspension (Ibi Sb) is attached to the ridge point· SS 1· Antenna device according to claim Ai characterized characterized in that the fastening device has a support (MS) extending away from the parabolic reflector (MO) - at the end point of which the suspension (Sb) of the magazine device (MM) is arranged. 10· Antenna device according to one of claims 7 to 1, characterized by an adjusting device (SAi 50) rigidly connected to the common fastening device (Ii MSi AS). ¹ " i2.ofl.nafl 11· Antenna device according to claim bt characterized characterized in that the individual spokes (fifii flii 1Oi Ili 13) of the spoke-shaped magazine device (flM) have different lengths or that the axis of rotation (flb) is arranged at an angle to the direction of incidence of the received radiation. 15· Antenna device according to claim 1, characterized in that the pole elements (β) are arranged so as to be adjustable along the individual spokes (Al). 13· Antenna device according to one of the preceding claimsi, characterized in that the focal elements (fi) are mounted in the magazine device (bi �Mgr;�Mgr;&Iacgr; 7Oi flM) so as to be rotatable about their transmission or reception direction. IM· Antenna device according to one of the preceding EO claimsi, characterized in that incident or outgoing electromagnetic radiation can be rotated by deflection elements about the direction of incidence or output* E5 15* Antenna device according to one of the preceding claims, characterized in that the receiving part and down-converter are integrated in the focal elements. It. Antenna device according to one of the preceding Claims&igr; characterized in that the magazine device (bi IMi 7Oi AM) has a high-frequency relay. By means of which only the focal element (fi) located in the focal point (Sfci bfii IM-. IS-, Ib-, 17) of the bundling device is connected to a line for supplying the signals to be transmitted. or is connected to a line for the transmission of the received signals 17· Antenna device according to one of the preceding claims·! characterized! in that the antenna device has a transmitter OS) and/or a receiver OS) for electromagnetic radiation in the frequency range of radio or television waves.
10 Ifi. Antenna device according to claim 17i, characterized in that the transmitter OB) and/or receiver OE) is arranged on the magazine device <bi MMi 7Qi β&Mgr;)·
15 &Pgr;. Antenna device according to one of the preceding claims, characterized by a servomotor (2bi &Mgr;&bgr;) for rotating the magazine device and a control device for automatically rotating the respective required focal element (&bgr;) in the focal point <2b* h&\ ¹ IM-, 15-, Ib-. ¹ I?) by means of the servomotor· 20· Antenna device according to one of the preceding claims, characterized in that at least the receiving or transmitting openings of the focal elements (β) are covered with a protective cover that essentially does not affect high-frequency radiation*
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