WO2015007726A1 - Assembly and method for installing a direction-finding antenna in a radome, preferably for retrofitting a direction-finding antenna in a radome - Google Patents

Abstract

The invention relates to an assembly for installing a direction-finding antenna in a radome, preferably for retrofitting a direction-finding antenna in a radome, comprising: at least one antenna element, which is attached to the inside of an outer shell of the radome, wherein the direction-finding antenna is suitable preferably for use in an interferometer direction-finding method and/or in an Adcock direction-finding method, especially preferably for use in a correlative interferometer direction-finding method, and further especially preferably for use in mobile systems suitable for performing at least one of said direction-finding methods. The invention further relates to a method for installing a direction-finding antenna in a radome, preferably for retrofitting a direction-finding antenna in a radome, comprising the following step: attaching at least one antenna element to the inside of an outer shell of the radome, wherein the direction-finding antenna is suitable preferably for use in an interferometer direction-finding method and/or in an Adcock direction-finding method, especially preferably in a correlative interferometer direction-finding method, and further especially preferably for use in mobile systems suitable for performing at least one of said direction-finding methods.

Description

 The invention relates to an arrangement and a method for installing a DF antenna in a radome, preferably for retrofitting into a radome.

Locations that are undisturbed and free from reflectors are generally best suited for the installation of DF antennas, so as not to influence the DF accuracy as far as possible. Especially in mobile locations, such as mobile units, e.g. Vehicles and ships, a DF antenna mounting on the highest point of the mobile unit, e.g. of the vehicle or the ship, sought. However, modern mobile units usually have a large number of different antennas, not just DF antennas, and sensors, some of which also claim the best possible location location on the vehicle and / or carrier tip.

DF antennas have to operate in a very wide frequency range today, for example, a VHF / UHF DF antenna must cover a frequency range of at least 20 MHz to 3 GHz. In general, such frequency ranges can not be realized with sufficient efficiency with only one DF antenna system and these DF antennas must generally consist of several subsystems. The DF antenna subsystems for the upper frequency ranges usually have small dimensions and can be accommodated on a mobile unit, for example on a vehicle and / or a ship, usually without problems or major difficulties. DF subsystem for lower frequencies have due to the correspondingly large wavelength, for example, from 20 MHz about 15 m, correspondingly larger dimensions. In general, for deeper frequencies, it is desirable to have dipoles with a correspondingly large effective height. For mobile applications DF antennas are often built in a compact design, the DF antenna subsystems for the upper frequency ranges to the antenna center usually have smaller dimensions and can be realized with sufficient efficiency. The dimension of the antenna subsystem for the lower frequency ranges are available in antennas in a compact design by the given available Overall antenna height determined so that a sufficient or desired efficiency can not be optimally realized and in the compact design inevitably a compromise between the dimensions in particular the antenna height and the antenna sensitivity thus achievable must be concluded.

Bearing systems with dimensions which are optimal in terms of sensitivity have dipoles in the order of less than one meter to several meters, preferably from 0.8 to 1.8 meters, particularly preferably one meter, for the lower frequency ranges and can be mounted on mobile units, for example Vehicles and / or ships, not easily attach. Optimally, the DF antenna subsystem with the largest dimensions for the low frequency range should be on the carrier tip. This achieves optimal antenna sensitivity. Such an arrangement with correspondingly complex, special construction is usually possible only with special vehicles. Modern mobile systems such as vehicles and / or ships do not allow this construction due to space limitations.

In the manual "Funkpeiltechnik" by Rudolf Grabau and Klaus Pfaff, Franckh'sche Verlagshandlung, W. Keller & Co., Stuttgart 1989, page 411, a DF antenna is shown with multiple DF systems.

DE 101 03 965 C2 relates to a single or multiple antenna bearing system,

for example, by the Adcock method for use in preferably

Mobile systems under difficult mechanical and climatic stress, wherein an antenna construction comprises a plurality of antenna radiators.

The invention has for its object an arrangement and a method for installing a DF antenna in a radome, preferably for retrofitting into a radome to provide. This object is achieved with one of the methods and a device according to the

independent claims solved. The dependent claims relate to further aspects of the invention.

The invention is based on the basic idea of providing an arrangement for, preferably retrofitting, Peilantenneneinbau in a radome of an existing satellite and / or sensor system on a vehicle and / or a ship, in which the retrofitted antenna elements, such as dipoles, be subsequently attached to the inner wall of the radome. The number of antenna elements depends on the selected DF method. The retrofitted antenna elements or dipoles can be subsequently glued into the radome of metallic self-adhesive film.

The invention relates to an arrangement for installing a DF antenna in a radome, preferably for subsequent installation in a radome, comprising: at least one

Antenna element which is mounted on the inside of an outer shell of the radome, and wherein the DF antenna is preferably for use in an interferometer and / or in an Adcockpeilverfahren, more preferably in a

 orrelativinterferometerpeilverfahren is suitable.

Furthermore, the DF antenna may be particularly suitable for use in mobile systems, wherein the mobile systems are suitable for carrying out at least one of said DF methods.

A radome can have a radome and / or a closed or at least partially closed protective sleeve enclosing antennas for measurements and / or data transmissions, for example direction finding antennas. A radome can have a bottom plate. This bottom plate can be arranged parallel to the ground or at an angle to the ground.

A radome can have a circular base. Furthermore, the radome may be spherical or cylindrical with a spherical dome

Have outer shell. Furthermore, the outer shell may be in the shape of an icosahedron, an icosahedral stump, a dodecahedron, or any other polyhedron. The outer shell of the radome may comprise a flexible material and / or a rigid material. The outer shell of the radome may in particular be suitable for protecting the antennas enclosed by the outer shell of the radome from external mechanical and / or chemical influences, for example wind, rain or seawater.

A mobile system may be a land vehicle, an aircraft, and / or preferably a ship. The antenna elements may be arranged on the entire Radomfläche.

 In one embodiment, the at least one antenna element may be mounted in the lower half of the inside of the outer shell of the radome and / or in the upper half of the inside of the outer shell of the radome. According to a further embodiment, the arrangement has a plurality of antenna elements, preferably 7 antenna elements, wherein the plurality of antenna elements

preferably equidistantly mounted on the inside of an outer shell of the radome. In particular, equidistant may mean that the plurality of antenna elements are equidistant from each other along the circumference of the radome. For example, in the embodiment with 7 antenna elements, each antenna element "n" is arranged at a position n-360 ° / 7, where n = 1, 2, 3, ..., 7. In particular, for example, in an embodiment with "m" Antenna elements of each antenna element "n" may be arranged at a position n-360 ° / m, where n = 1, ..., m. More preferably, the arrangements 4, 5, 7, 8, or 9 may comprise antenna elements.

In a further embodiment, the at least one antenna element has a dipole antenna or the multiple antenna elements each have a dipole antenna, wherein the dipole antenna or the respective dipole antenna has a long and a short extension direction and wherein the long extension direction of the dipole antenna or the respective dipole antenna is preferably aligned perpendicular to the circumferential direction of the radome. A dipole antenna can be a broadband dipole antenna, preferably suitable for large frequency ranges.

According to a further embodiment, the at least one antenna element is glued to the inside of the outer shell of the radome. This can also be at least one

 Antenna element have a self-adhesive, metallic foil and / or have at least one flexible circuit board. The at least one antenna element can also be metallically deposited on the inside of the outer shell of the radome. The self-adhesive metallic foil may comprise aluminum and / or copper. The at least one antenna element can also be metallically deposited on the inside of the outer shell of the radome made of aluminum, copper and / or silver. Furthermore, at least one insulation and / or protective layer can be vapor-deposited and / or applied.

In a further embodiment arrangement, the antenna element (s) form a DF antenna subsystem, and the DF antenna subsystem can be combined with at least one further subsystem, wherein the arrangement particularly preferably comprises at least one feed line for relaying antenna signals from the at least one antenna element to at least one antenna electronics ,

An antenna electronics may have a matching amplifier and / or an amplifier and / or switching elements. A feed line may be adapted to receive antenna signals from the at least one

 Loop antenna element to at least one element of the antenna electronics. Such a feed line may be an insulated copper line, for example a

Coaxial cable, or a fiber optic cable. Also, a feeder may be made up of multiple copper or fiber optic cables or a combination of copper and fiber optic cables. According to a further embodiment, the at least one feed line is divided into a first part with the length Sl and a second part with the length S2, wherein the

Feed line is connected to one end of the first part with the at least one antenna element, wherein the first part is aligned substantially parallel to the circumferential direction of the radome and / or wherein the second part substantially perpendicular to

Circumferential direction is aligned in the direction of a bottom plate of the radome. The lengths Sl and S2 can be the same or different. The two parts of the feed line can be clearly separated from each other and / or be configured in two parts. The two parts of the feed line can also be designed in one piece and / or designed indistinguishable.

In a further embodiment, the arrangement has at least one first and one second antenna element and at least one first and one second feed line. Here, the first feed line is divided into a first part with the length Sl and a second part with the length S2 and the second feed line into a first part with the

Length Sl 'and a second part with the length S2' is divided. The first feed line is connected to one end of the associated first part with the first antenna element and the second feed line is connected to one end of the associated first part to the second antenna element. The first parts of the first and second

Feed line are aligned substantially parallel to the circumferential direction of the radome and / or the second parts of the first and second feed line are adjacent and oriented substantially perpendicular to the circumferential direction in the direction of a bottom plate of the radome. The number of antenna elements is preferably greater than the number of elements of the at least one antenna electronics. The lengths S 1 and S2 may be the same or different. Also, the lengths S 1 and S 1 'or S2 and S2' may be the same or different.

According to a further embodiment, the number of at least one

Antenna element selected depending on the DF method to be used.

Thus, in the case of an Adcock or an Adcock / Watson Watt direction finding method, preferably 4 or 8 antenna elements can be attached. In an interferometer Bearing method and / or a correlative interferometer DF method preferably 5 or 9 antenna elements, particularly preferably in a correlative interferometer DF method 7 antenna elements, are attached. According to the invention an adom with a DF antenna according to the above

Description provided.

In a further embodiment, an interior of the radome has at least one further device for locating and / or receiving and / or transmitting radio signals, preferably satellite signals, and / or at least one sensor system.

A sensor system may include a radar antenna. An apparatus for receiving and transmitting radio signals may comprise an antenna for satellite navigation. The invention also relates to a method for installing a DF antenna in a radome, preferably for subsequent installation in a radome, with the following step:

Attaching at least one antenna element to the inside of an outer shell of the radome, wherein the DF antenna preferably for use in an interferometer, a correlative interferometer and / or in an Adcock DF method, wherein the DF antenna preferably for use in an interferometer and / or in a

Adcockpeilverfahren, particularly preferably in a correlativinterferometerpeilverfahren and further particularly preferred for use in mobile systems suitable for carrying out at least one of the aforementioned Beilverfahren is suitable. The antenna elements may be arranged on the entire Radomfläche.

According to one embodiment, the at least one antenna element is mounted in the lower half of the inside of the outer shell of the radome and / or in the upper half of the inside of the outer shell of the radome. In a further embodiment, in the method a plurality of antenna elements are mounted, preferably 7 antenna elements, wherein the plurality of antenna elements preferably be equidistantly mounted on the inside of an outer shell of the radome.

According to a further embodiment, in the method, the at least one antenna element has a dipole antenna or the plurality of antenna elements each have a dipole antenna, wherein the dipole antenna or the respective dipole antenna has a long and a short extension direction and wherein the long

Extension direction of the dipole antenna or the respective dipole antenna is preferably aligned perpendicular to the circumferential direction of the radome.

In a further embodiment, the method has the following further steps:

Sticking the at least one antenna element to the inside of the outer shell of the radome and / or metallic vapor deposition of the at least one antenna element to the inside of the outer shell of the radome.

According to a further embodiment, the method has the fastening, preferably sticking, of the at least one antenna element as a self-adhesive metallic foil and / or of the at least one antenna element in the form of at least one flexible printed circuit board.

In a further embodiment, the method comprises the further steps:

Forming a DF antenna subsystem of antenna elements, and preferably

Combining the DF antenna subsystem with at least one further subsystem, preferably with the further step:

Connecting at least one feed line to the at least one antenna element and at least one antenna electronics, wherein the at least one feed line to

Forwarding of antenna signals from the at least one antenna element to the at least one antenna electronics is suitable. According to a further embodiment, in the method, the at least one

Feed line in a first part with the length Sl and a second part with the length S2 divided, wherein the feed line with one end of the first part with the at least an antenna element is connected, wherein the first part is aligned substantially parallel to the circumferential direction of the radome and / or wherein the second part in

Aligned substantially perpendicular to the circumferential direction in the direction of a bottom plate of the radome.

In a further embodiment, in the method at least a first and a second antenna element are attached and connected to at least a first and a second feed line,

wherein the first feed line is subdivided into a first part of length Sl and a second part of length S2, and the second feed line is subdivided into a first part of length Sl 'and a second part of length S2',

wherein the first feed line is connected to one end of the associated first part to the first antenna element and the second feed line is connected to one end of the associated first part to the second antenna element, and

wherein the first parts of the first and second feeders are aligned substantially parallel to the circumferential direction of the radome and / or

wherein the second parts of the first and second feeders are adjacent and aligned substantially perpendicular to the circumferential direction towards a bottom plate of the radome, and

wherein preferably the number of antenna elements is greater than the number of elements of the at least one antenna electronics.

According to another embodiment, in the method, the number of the at least one antenna element to be attached depends on the one to be used

Direction finding method selected.

In a further embodiment, in the method, the radome has at least one further device for locating and / or receiving and / or transmitting radio signals, preferably satellite signals, and / or at least one sensor system.

It shows: Figure 1 is a schematic drawing of an arrangement for mounting a DF antenna in a radome according to an embodiment of the invention, and

Figure 2 is a schematic drawing of an arrangement for installation of a DF antenna in a radome according to another embodiment of the invention.

Figure 1 shows a schematic drawing of an arrangement for installation of a DF antenna in a radome according to an embodiment of the invention. To the inside of the outer shell of the radome 300 a plurality of antenna elements 101 of the arrangement along the Radomumfangs are glued equidistant. The several

Antenna elements 101 are each configured as dipole antennas and each have a short and a long extension direction. The long extension directions of the dipole antennas are aligned parallel to each other and perpendicular to the circumferential direction of the radome 300 and the bottom plate or bottom frame 500 of the radome 300, respectively.

The antenna elements 101 designed as dipole antennas are connected via a

Connecting element 103 respectively connected to supply lines 102, wherein the

Supply line 102 is divided into a first part with a length Sl and a second part with the length S2. The first part is the part connected to the antenna element 101. The first part is aligned substantially parallel to the circumferential direction of the radome 300 and thus aligned according to the present embodiment perpendicular to the long extension direction of the antenna element 101. The second part of the

Feeder line 102 of length S2 is oriented substantially perpendicular to the circumferential direction and thus parallel to antenna element 101 in accordance with the present embodiment. The second part with the length S2 of the feed line 102 has in

Direction of the bottom plate of the radome. The second part of the feed line 102 is further provided with an element 201 of a

Antenna electronics connected. The antenna electronics can be used for further processing and / or forwarding the direction finding signals received by the antenna element 101 be suitable. The antenna electronics elements 201 are mounted on the floorstand 500 according to the present embodiment.

In the radome 300 is also a parabolic antenna 400, the

Satellite communication is suitable.

Figure 2 shows a schematic drawing of an arrangement for mounting a DF antenna in a radome 300 according to another embodiment of the invention. As in the first embodiment shown in FIG. 1, in the radome there is a satellite antenna 400 for satellite communication.

In this embodiment, too, antenna elements 101 and 101 'of an assembly for mounting a sub-antenna in a radome along the circumference of the radome are adhered to the inside of the outer shell of the radome 300. The antenna elements 101 and 10Γ in this embodiment are also formed as dipole antennas, and the long extension directions of the antenna elements 101 and 101 'are aligned parallel to each other and perpendicular to the bottom plate and the bottom frame 500 and perpendicular to the circumferential direction of the radome 300, respectively. The antenna element 101 is connected to a feed line 102 via a connecting element 103 and the antenna element 101 'is connected to the feed line 102' via a connecting element 103 '. The

Feeding line 102 is divided into a first part of length Sl and a second part of length S2. The second feed line 102 'is divided into a first part with the length Sl' and a second part with the length S2 '. In this case, the first feed line 102 is connected to one end of the associated first part via the connecting element 103 to the first antenna element 101 and the second feed line 102 'is connected to one end of the associated first part to the second antenna element 101'. The first parts of the first and second feeders 102 and 102 'are aligned parallel to the circumferential direction and parallel to the bottom plate or base 500. In contrast to the embodiment shown in Figure 1, the second parts with the length S2 or S2 'of the first and second feed line 102 and 102' adjacent, ie preferably mounted at a distance of a few millimeters to a few centimeters. Also, the second parts of length S2 and S2 'are the first and second Feed line 102 and 102 'perpendicular to the circumferential direction and thus aligned parallel to the long extension direction of the antenna elements 101 and 10, respectively. The second parts of the first and second feeders 102 and 102 'are provided with a

common element 201 connected to an antenna electronics. Therefore, this is

Embodiment particularly suitable when fewer elements 201 of the

 Antenna electronics as antenna elements 101 and 101 'are available.

Although the invention has been described and illustrated in detail by the invention and the accompanying description, these drawings and this detailed description are to be considered as illustrative and exemplary and not as limiting the invention. It is understood that professionals can make changes without departing from the scope and spirit of the following claims. In particular, the invention also includes embodiments with a combination of features, which are mentioned or shown above or below different embodiments.

The invention also includes individual features in the figures, even though they are shown there in connection with other features and / or are not mentioned above or below. Also, the alternatives of embodiments described in the figures and the description and individual alternatives whose features may be excluded from the subject invention or from the disclosed subject matter. The disclosure includes embodiments that include only the features described in the claims and in the embodiments, as well as those that additionally include other features.

Claims

 claims 1. Arrangement for installing a DF antenna in a radome, preferably for  retrofitting into a radome, with:  at least one antenna element, which is attached to the inside of an outer shell of the radome, and  wherein the DF antenna is preferably for use in an interferometer and / or in an adcock bearing method, more preferably in a  Correlative interferometric methods and further particularly preferred for use in mobile systems suitable for carrying out at least one of said  Bearing method is suitable. 2. Arrangement according to claim 1, wherein the at least one antenna element in the  lower half of the inside of the outer shell of the radome and / or in the upper half of the inside of the outer shell of the radome is mounted. 3. Arrangement according to claim 1 or 2, with a plurality of antenna elements, preferably 7 antenna elements, wherein the plurality of antenna elements are preferably mounted equidistantly on the inside of an outer shell of the radome. 4. Arrangement according to one of claims 1 to 3, wherein the at least one  Antenna element has a dipole antenna or the plurality of antenna elements each having a dipole antenna, wherein the dipole antenna or the respective dipole antenna has a long and a short extension direction and wherein the long extension direction of the dipole antenna or the respective dipole antenna is preferably aligned perpendicular to the circumferential direction of the radome. 5. Arrangement according to one of claims 1 to 4, wherein the at least one Antenna element is glued to the inside of the outer shell of the radome and / or has a self-adhesive, metallic foil and / or at least one flexible Circuit board and / or is metallically deposited on the inside of the outer shell of the radome. Arrangement according to one of claims 1 to 5 wherein the one or more antenna elements form a DF antenna subsystem, and the DF antenna subsystem is combinable with at least one further subsystem, the arrangement particularly preferably comprises at least one feed line for transmitting antenna signals from the at least one antenna element to at least one antenna electronics. Arrangement according to claim 6, wherein the at least one feed line is divided into a first part with the length Sl and a second part with the length S2, wherein the feed line with one end of the first part with the at least one Antenna element is connected, wherein the first part is aligned substantially parallel to the circumferential direction of the radome and / or wherein the second part is aligned substantially perpendicular to the circumferential direction in the direction of a bottom plate of the radome. Arrangement according to claim 6, with at least a first and a second Antenna element and at least a first and a second feed line, wherein the first feed line is divided into a first part with the length Sl and a second part with the length S2 and the second feed line in a first part with the length Sl 'and a second part with the length S2 'is divided, wherein the first feed line is connected to one end of the associated first part to the first antenna element and the second feed line is connected to one end of the associated first part to the second antenna element, and wherein the first parts of the first and second feed lines are substantially parallel to the circumferential direction the radome are aligned and / or wherein the second parts of the first and second feeders are adjacent and aligned substantially perpendicular to the circumferential direction towards a bottom plate of the radome, and wherein preferably the number of antenna elements is greater than the number of elements of the at least one antenna electronics. 9. Arrangement according to one of claims 1 to 8, wherein the number of at least one antenna element is selected depending on the DF method to be used. 10. Arrangement according to one of claims 1 to 9, wherein an interior of the radome  at least one further device for locating and / or receiving and / or transmitting radio signals, preferably satellite signals, and / or at least one  Having sensor system. 11. A method for installing a DF antenna in a radome, preferably for  retrofitting into a radome, with the following step:  Attaching at least one antenna element to the inside of an outer shell of the radome,  wherein the DF antenna is preferably for use in an interferometer, a correlative interferometer and / or an Adcock direction finding method, wherein the  Direction finding antenna preferably for use in an interferometer and / or in an adcock bearing method, more preferably in one  Correlative interferometric methods and further particularly preferred for use in mobile systems suitable for carrying out at least one of said  Bearing method is suitable. 12. The method of claim 11, wherein the at least one antenna element in the  lower half of the inside of the outer shell of the radome and / or in the upper half of the inside of the outer shell of the radome is mounted. 13. The method of claim 11 or 12, wherein a plurality of antenna elements are mounted, preferably 7 antenna elements, wherein the plurality of antenna elements are preferably mounted equidistantly on the inside of an outer shell of the radome. 14. The method according to any one of claims 11 to 13, wherein the at least one Antenna element has a dipole antenna or the plurality of antenna elements each having a dipole antenna, wherein the dipole antenna or the respective dipole antenna has a long and a short extension direction and wherein the long extension direction of the dipole antenna or the respective dipole antenna is preferably aligned perpendicular to the circumferential direction of the radome. 15. The method according to any one of claims 11 to 14, comprising the steps of: adhering the  at least one antenna element to the inside of the outer shell of the radome and / or metallic vapor deposition of the at least one antenna element to the inside of the outer shell of the radome. 16. The method according to any one of claims 11 to 15, with the further steps: attaching the at least one antenna element as a self-adhesive, metallic foil and / or the at least one antenna element in the form of a flexible printed circuit board. 17. The method according to any one of claims 11 to 16 with the further steps:  Forming a DF antenna subsystem of antenna elements, and preferably combining the DF antenna subsystem with at least one further subsystem, preferably with the further step:  Connecting at least one feed line to the at least one antenna element and at least one antenna electronics, wherein the at least one feed line for forwarding antenna signals from the at least one antenna element to the at least one antenna electronics is suitable. The method of claim 17, wherein the at least one feed line is divided into a first part having the length Sl and a second part having the length S2, wherein the feed line with one end of the first part with the at least one Antenna element is connected, wherein the first part is aligned substantially parallel to the circumferential direction of the radome and / or wherein the second part is aligned substantially perpendicular to the circumferential direction in the direction of a bottom plate of the radome. 19. The method of claim 17, wherein at least a first and a second  Antenna element attached and connected to at least a first and a second feed line,  wherein the first feed line is subdivided into a first part of length Sl and a second part of length S2, and the second feed line is subdivided into a first part of length Sl 'and a second part of length S2',  wherein the first feed line is connected to one end of the associated first part to the first antenna element and the second feed line is connected to one end of the associated first part to the second antenna element, and wherein the first parts of the first and second feed lines are substantially parallel to the circumferential direction the radome are aligned and / or  wherein the second parts of the first and second feeders are adjacent and aligned substantially perpendicular to the circumferential direction towards a bottom plate of the radome, and  wherein preferably the number of antenna elements is greater than the number of elements of the at least one antenna electronics. 20. The method according to any one of claims 11 to 19, wherein the number of at least one antenna element to be attached is selected depending on the DF method to be used. 21. The method according to any one of claims 11 to 20, wherein the radome at least one further device for locating and / or receiving and / or sending  Radio signals, preferably satellite signals, and / or at least one sensor system.