DE202010016969U1 - Electronic receiving antenna - Google Patents

Abstract

An electronic receiving antenna having an antenna assembly in the form of a printed circuit board (1) with a dielectric support (2), wherein the support (2) is cup-shaped with a metallized interior and the printed circuit board (1) of the antenna unit is located at the top of the support (2) and covered with a radio-transparent layer using a low noise amplifier (4) with a filter disposed on the lower metallised surface of the carrier (2), a bridge (11) connecting the printed circuit trace (1) to the input the low-noise amplifier (4) connects and wherein a coaxial cable (7) with an RF cable connector (8) at its end and a flap (9) are provided,
characterized,
in that the low-noise amplifier (4) is designed in two stages in the form of a micro-module with an upstream limiter diode assembly (5), that a ceramic antenna filter (6) is constructed between the stages of the amplifier (4),
that the antenna filter (6) to the outer terminals of the ...

Description

The invention relates to an electronics receiving antenna according to the preamble of claim 1.

The invention can be used in radio technology and in particular for antennas. It can be used for reception, amplification and radio signal filtering. In particular, the invention can be applied as an electronics receiving antenna in the equipment technology of the users of space navigation systems (GPS, GLONASS / GPS / GALILEO).

From the prior art, an electronic navigation receiving antenna in the form of a module is known. It has a polycarbonate housing. The polycarbonate enclosure consists of a protective cover and a lower flap with elements for attachment to a conductive screen. The known antenna also has an amplifier with filters, an antenna unit and a cable with a plug-in terminal at its end, which are formed in the form of an assembly. The amplifier and the filters are covered with a metal screen. The antenna unit with the amplifier is inserted into the module housing. The cable is led out to the outside. The cable exit point on the housing is mechanically pressed ( Motorola GPS Products - On core User's Guide Revision 5.008 / 30/02, Motorola website: http://www.motorola.com/ru/ ).

This structure does not ensure sufficient mechanical strength of the antenna. Also, no adequate antenna gain is ensured at angles close to the screen surface. This causes signal loss from the Sputniks near the horizon. In addition, the antenna is not waterproof enough because the connection points are not sealed. In addition, the known antenna is large and structurally complicated.

From the prior art ( GPS Antenna / Rev.2.05 (8/18/97), Motorola website: http://www.motorola.com/ru/ Also known is an electronics receiving antenna. This electronic receiving antenna has a printed circuit board with a ceramic carrier, a low noise amplifier with ceramic filters, a coaxial cable with an RF cable connector at its end and a flap with fasteners. The fasteners are used for attachment to a conductive screen. This antenna has no mounting holes in the lower flap. When attaching the electronic antenna to the non-magnetic screen, an adapter steel plate is additionally used.

However, this antenna does not ensure sufficient mechanical strength and operational safety. It also does not guarantee the required directional characteristics. In addition, this antenna has large dimensions and a complicated structure.

The closest prior art to the invention is an electronic antenna according to the patent RU 2274934 (published on 20.04.06). This known antenna comprises an antenna unit in the form of a printed circuit board with a ceramic carrier, a low-noise amplifier with ceramic filters, a coaxial cable with an RF cable connector at its end and a flap with fasteners. The fasteners are used for attachment to a conductive screen. In this case, a carrier of the antenna unit is designed as a ceramic cup-shaped housing with a metallized interior with a shoulder. The printed conductor of the antenna unit is arranged at the tip of the carrier. The printed circuit board is covered with a radio-transparent protective layer. In this case, the low-noise amplifier is arranged on the lower metallized surface in the interior of the ceramic housing. The coaxial cable end passes through a metallized side bore of the carrier. The carrier is covered by the internally metallized flap with a magnet and a threaded bushing. The threaded bushing is mounted on the shoulder of the interior of the wearer.

The shortcomings of this device include the large dimensions and the complicated structure.

It is an object of the invention to reduce the antenna dimensions, to simplify the structural design and to increase the manufacturing accuracy and reliability of the electronic receiving antenna.

The stated object is solved by the features of claim 1.

The low-noise amplifier is designed in two stages. It consists of a micro-assembly and a limiter diode module connected in front of it. Between the amplifier stages, a ceramic antenna filter is constructed. The antenna filter is connected to the outside of the micro-assembly. The flap is magnetically formed. The antenna unit, the flap and the cable end are covered with a protective plastic layer. In an AOW filter, the interior of the dielectric housing is filled with a sealant.

The invention will be explained in more detail with reference to an embodiment shown in the drawing.

The electronics receiving antenna consists of an antenna unit. The antenna unit comprises a printed conductor track 1 and a dielectric carrier 2 with a metallised lower shielding inner surface 3 , Subassemblies (boards) of a low-noise amplifier 4 with a limiter diode assembly 5 and a ceramic filter 6 , a high-frequency cable 7 with an RF cable connector 8th at the end of the cable, a flap 9 , a plastic protective layer 10 and a bridge 11 ,

The dielectric carrier 2 The antenna unit is a cup-shaped housing with the metallized Abschirminnenfläche 3 and a metallized bore formed in the side wall. The printed circuit trace 1 Any shape is at the top of the carrier 2 arranged. The carrier 2 The antenna unit can be formed both of high-strength ceramic as well as of dielectric plastic. A second embodiment of the carrier housing is cheaper but not so robust.

The assembly of the low-noise amplifier 4 is at the metallized bottom surface of the dielectric support 2 attached in the interior of the cup-shaped housing. The assembly of the low-noise amplifier 4 includes the actual two-stage amplifier, the Begrenzerdiodenbaugruppe 5 and the ceramic filter 6 , The amplifier 4 is designed as a micro-module. The limiter diode assembly 5 is upstream of the micro-assembly. The ceramic filter 6 is connected between the amplifier stages to the outer terminals of the micro-assembly.

According to one embodiment, the ceramic filter 6 formed in a sealed housing in the form of an AOW filter (surface acoustic wave filter). The interior of the carrier housing is filled with a sealant.

The ceramic filter as well as the AOW filter are the first gain stage of the low-noise amplifier 4 downstream. The input of the low-noise amplifier 4 is electrically by means of the bridge 11 with the conductor track 1 connected to the antenna unit. This ensures a line-connected connection. In this case, the connection point is selected on the assumption of an optimal matching with respect to impedance.

The high frequency cable 7 Used to connect the output of the low-noise amplifier 4 with a receiving device. An end of the high frequency cable 7 runs through the side hole in the carrier 2 and occupies the output of the module (board) of the low-noise amplifier 4 , At the other end is the RF cable connector 8th soldered.

The flap 9 is formed of a conductive material with remanence. It is connected to the dielectric housing. The flap 9 also serves to attach the electronic antenna to a conductive screen 12 , This forms a so-called magnetic closure.

The antenna unit and the flap 9 are with a plastic protective coating 10 covered. The plastic protective layer 10 is at the high frequency cable 7 extended in the form of a neck.

The antenna unit is through the conductor track 1 and the dielectric carrier 2 with the metallized lower shielding inner surface 3 educated. The electromagnetic wave is incident on the antenna unit having a broad directional characteristic. In this case, in the antenna unit, HF oscillations are produced which generate HF currents on the current conducting surfaces of the antenna unit.

The expansion of the directional characteristic takes place thanks to the lifting of the antenna unit over the surface of the screen 12 , This is achieved by the fact that the dielectric carrier 2 is formed with a metallized lower surface in the form of a turned-over cup. At the top of the mug is the printed trace 1 arranged in any shape. The presence of a dielectric layer on the side surface of the cup makes it possible to expand the directional characteristic even more.

The one in the track 1 resulting HF current flows over the bridge 11 to the input of the low-noise amplifier 4 , The low noise amplifier 4 is located in a closed space, which through the metallized interior of the dielectric housing and the conductive (metallized) flap 9 is formed. The low noise amplifier 4 is isolated from direct action of incident electromagnetic waves. The signal is in the low noise amplifier 4 reinforced, by means of the ceramic filter 6 filtered and comes over the high-frequency cable 7 with the RF cable connector 8th to the entrance of the receiving device.

The at the entrance of the low-noise amplifier 4 provided limiter diode assembly 5 serves the input stage of the low-noise amplifier 4 to protect against failure in the input of a foreign high-power signal (fault).

The execution of the two-stage amplifier 4 in a micro-assembly, uniting the flap and magnet functions in the flap 9 made of magnetized material, the formation of the unitary and the housing, the flap 9 and the cable entry comprehensive plastic protective layer allow the antenna dimensions too reduce the structural design, improve the manufacturing accuracy and increase the reliability of the electronic receiving antenna.

The filling of the interior of the dielectric housing support with a sealant in the circuit of the low-noise amplifier 4 AOW filter with sealed housing affects the function of the amplifier 4 not considering this priming. However, it makes it possible to carry out the antenna absolutely tightly and with maximum reliability.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• RU 2274934 [0007]

Cited non-patent literature

• Motorola GPS Products - On core User's Guide Revision 5.008 / 30/02, Motorola website: http://www.motorola.com/ru/ [0003]
• GPS Antenna / Rev.2.05 (8/18/97), Motorola website: http://www.motorola.com/ru/ [0005]

Claims (9)

Electronics receiving antenna having an antenna assembly in the form of a printed circuit trace ( 1 ) with a dielectric support ( 2 ), the carrier ( 2 ) cup-shaped with a metallized interior and the printed circuit trace ( 1 ) of the antenna unit at the tip of the carrier ( 2 ) and covered with a radio-transparent layer, wherein a low-noise amplifier ( 4 ) is used with a filter attached to the lower metallised surface of the support ( 2 ), wherein a bridge ( 11 ) the printed circuit trace ( 1 ) with the input of the low-noise amplifier ( 4 ) and where a coaxial cable ( 7 ) with an RF cable connector ( 8th ) at its end and a flap ( 9 ), characterized in that the low-noise amplifier ( 4 ) in two stages in the form of a micro-assembly with an upstream limiter diode assembly ( 5 ) is formed, that between the stages of the amplifier ( 4 ) a ceramic antenna filter ( 6 ) is constructed so that the antenna filter ( 6 ) is connected to the outer terminals of the micro-assembly and that the flap ( 9 ) is magnetically formed and the antenna assembly the flap ( 9 ) and the cable end covered with a plastic layer. Electronics receiving antenna according to claim 1, characterized in that the interior of the dielectric housing carrier ( 2 ) is filled with a sealant, which is the circuit of the low-noise amplifier ( 4 ) of the SAW filter ( 6 ) in the sealed housing. Electronics receiving antenna according to claim 1 and 2, characterized in that the cup-shaped carrier ( 2 ) is provided with a metallized bore in its side wall and that the bore in a metallized neck for the coaxial cable ( 7 ) passes over. Electronics receiving antenna according to claim 3, characterized in that also the nozzle with the plastic layer ( 10 ) is covered. Electronics receiving antenna according to claim 1 to 4, characterized in that the low-noise amplifier ( 4 ) with the lower surface ( 3 ) of the carrier ( 2 ) is connected in the interior of the housing. Electronics receiving antenna according to claim 1 to 5, characterized in that the filter ( 6 ) is designed as an AOW filter (surface acoustic wave filter). Electronics receiving antenna according to claim 1 to 6, characterized in that the antenna unit, the amplifier ( 4 ) and the filter ( 6 ) of a magnetic flap ( 9 ) are covered with remanence. Electronics receiving antenna according to claim 1 to 7, characterized in that the carrier ( 2 ) of the antenna unit made of high-strength ceramic or dielectric plastic. Electronics receiving antenna according to claim 1 to 8, characterized in that the antenna unit with the flap ( 9 ) and the socket for the coaxial cable with the plastic layer ( 10 ) are covered.

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