EP0837521A2 - Radio antenna array and patch antenna on a motor vehicle window - Google Patents

Abstract

The radio antenna arrangement includes a base plate (4) attached to the outside of the vehicle near the upper edge of the pane of an inclined windscreen (1) in a vehicle chassis. An emitter (3) is fastened to the base plate and extends from the plate. The arrangement also has an emitter connection point (2) between the emitter and the base plate. The base plate is conductive at least in parts and acts as an electric counterweight of the emitter. A thin antenna conductor (5) is connected to the emitter connection point. The antenna conductor is fed to the upper edge of a vehicle windscreen. The conductor is bent and is fed to the inner surface of the windscreen through an adhesive track (6) into the vehicle. As well as the emitter a patch antenna is fastened to the base plate. The patch antenna signal is fed from the antenna connection point either itself or via the thin antenna conductor (9) which runs from the windscreen to the upper edge then bends and is fed into the interior of the vehicle.

Description

The invention relates to a radio antenna arrangement for radio connections with terrestrial radio stations for decimeter and / or Centimeter waves, with one on the sloping window in an electrically conductive vehicle body 10 and at the top of the window mounted spotlight 3, which consists of a attached to the outside of the window pane 1, from this protruding antenna element 3 and this on one on the Window plate attached base plate 4 is attached with a radiator connection point 2. Radio antennas of this type e.g. known from DE .... as well as group antennas in DE .... The problems with these antennas exist among other things in the signal feed, which according to the prior art via capacitive coupling elements on the glass pane 1 is realized. Another problem is that in modern radio systems in vehicles often to communicate simultaneously with several radio services Has. The GSM system is an example of the radio telephone services (D network) and the mobile radio system E network as well as that in the USA used AMPS system called that in the frequency range of 800 MHz to 1900 MHz work. Often, in addition to the telephone service satellite radio service may be enabled, e.g. the global Positioning system (GPS), or a planned one bidirectional satellite radio service with low flying Satellite (Leos), or a receiving antenna for terrestrial Digital audio broadcasting signals in the L-band. All of the above Services operate in the range from 1400 to 1600 MHz. According to experience finds the attachment of several antennas on the vehicle low acceptance and there is a desire for a combination antenna which covers both radio services.

The object of the invention is therefore a radio antenna arrangement according to the preamble of claim 1 with a patch antenna for to combine the satellite radio services in a space-saving way, that the strong signal coupling due to the crowded structure in the transmission mode of one antenna, the reception with the other antenna is not disturbed.

This object is achieved by the characterizing Part of claim 1 solved.

Fig. 1
Antenne nach der Erfindung mit Strahler 3, Patchantenne 7, auf Grundplatte 4 und Antennenleitung 5, verlegt über die Oberkante der Glasscheibe durch die Kleberaupe 6 in den Fahrzeuginnenraum.

Fig. 2
Draufsicht auf eine Antenne nach der Erfindung mit Patchanordnung für kleinstmögliche Strahlungskopplung zwischen Strahler 3 und Patch 7.

Fig. 3
Funkgruppenantenne mit zwei Strahlern und dazwischenliegender Patchantenne 7 mit Vorverstärker.

Fig. 4a,b
Beispiel eines Blockschaltbilds der Antennenanordnung mit Bandsperren und Bandpässen im jeweiligen Funkdienst GSM und GPS.

Fig. 5
Ausführungsform einer Mehrfach-Flachbandleitung mit einer Streifenleitung für kleine Leistungen und einer Koplanarleitung für große Leistungen in Dreilagentechnik mit ausgesparten Masseflächen im Bereich der Koplanarleitung und Leiterbrücken zwischen den Masseflächen.

The invention is explained in more detail below with reference to the figures. In detail show:

Fig. 1
Antenna according to the invention with radiator 3, patch antenna 7, on base plate 4 and antenna line 5, laid over the upper edge of the glass pane through the adhesive bead 6 into the vehicle interior.

Fig. 2
Top view of an antenna according to the invention with a patch arrangement for the smallest possible radiation coupling between radiator 3 and patch 7.

Fig. 3
Radio group antenna with two radiators and patch antenna 7 with preamplifier in between.

4a, b
Example of a block diagram of the antenna arrangement with bandstops and bandpasses in the respective radio service GSM and GPS.

Fig. 5
Embodiment of a multiple ribbon cable with a strip line for small outputs and a coplanar line for large outputs in three-layer technology with recessed ground areas in the area of the coplanar line and conductor bridges between the ground surfaces.

Especially when attaching antennas to window panes it is necessary to see the visible area covered by the antenna to keep it as small as possible. Because of this, it is necessary the patch antenna 7, as in Fig. 1, close to the radiator 3 approach. The common base plate 4 serves both as electrical counterweight for the radiator 3 as well as for the Patch antenna 7. The radiation coupling between the radiator 3, which is designed as a rod radiator, and the patch antenna is smallest when the patch antenna as shown in FIG Spotlight is oriented, with the perpendicular bisector one Patch edge with the connecting line of the spotlight center whose lower end coincides with the center of the patch. Satellite radio services work for vehicle communication in the Frequency range around 1.5 GHz.

D-Netz / AMPs-Netz antennas operate in the frequency range around 800 MHz or 900 MHz. The resonance frequencies of the radiators and the Patch antennas are thus far enough apart. Also when using the cellular E network with its operating frequency around 1800 MHz the frequency spacing is sufficiently large to allow for the Arrange the patch antenna and the radiators so close together.

Especially when receiving GPS signals, it is necessary to Patch antenna without the interposition of lossy lines connect a low-noise preamplifier. This can expedient in an advantageous embodiment of the invention also be attached to the base plate 4 as it is made Fig. 3 emerges. In this example the patch antenna is in an embodiment of the invention between two emitters of the Mobile telephones arranged to save space. It is special Advantage of the invention that the DC power supply of the GPS antenna amplifier on the base plate 4, for example, over the signal-carrying conductor of an antenna line can take place. This ensures an optimal signal to noise ratio in the GPS reception system. The antenna characteristics of the patch antenna is normal to the glass pane with its main direction. The large opening angle of the antenna lobe in connection with the flat angles of inclination of current front or rear window arrangements ensures the necessary radio contact to the satellites.

A particular problem is the edge radiation of the cell phone radiators in the form of noise on the reception frequency of the Satellite antenna. It is therefore often necessary to do this Edge emission by a bandstop on the frequency of the Satellite reception, which is in the signal path between the antenna line 5 and cellular radiator is switched to suppress (see Fig. 4a).

In many cases, it is also useful to protect the received Satellite signal and to protect against the formation of interference frequencies through non-linear effects of received signals from the patch antenna, to add a bandpass. This protects the its output connected low noise amplifier from unwanted Signals. Because of the near field of cellular radiators it is extremely large field strengths according to the invention often beneficial between patch antenna and the above described subsequent circuit a bandstop on the Mobile radio frequency to introduce nonlinear effects in the Exclude components safely. Serves the same purpose according to the invention also a downstream of the preamplifier Band stop in the mobile radio frequency range (see Fig. 4b).

There is often a desire for a particularly flat antenna cable. This can preferably be carried out using multilayer technology will. In a particularly advantageous form, the Antenna line can be designed as a multiple line. At very thin lines in stripline technology there is the problem that the signal-carrying conductor is extremely narrow must be realized so that a wave resistance of 50 ohms is realized can be. To ensure good decoupling between the individual antenna lines of the multiple line, is designed in three-layer technology, as in Fig. 5. Here the signal-carrying conductor can be very narrow between the be embedded in both outer ground surfaces. The outer Ground areas are spaced at appropriate intervals using Vias 19 connected to each other. Because of the very narrow signal-carrying conductor 20 can only relatively small high-frequency powers are transmitted, such as as reception powers of a satellite signal given are. In contrast to that, is the cellular antenna High-frequency power to be transmitted for one line this shape too big.

In an advantageous embodiment of the invention therefore, as in Fig. 5, a comparatively broad signal-carrying Head 21 in the middle position of the three-layer arrangement trained as a coplanar line. The two outer conductor layers are too large to avoid capacities removed in the area of the coplanar line. To still be one electrical connection between the outer metal coverings of the To produce multiple lines become small at intervals compared to the wavelength, narrow conductor bridges 22 are such designed that the wave resistance requirement at the Frequency is satisfied. With the help of appropriately attached Vias 19, the ground surfaces 24 on both sides of the multiple line electrically connected will.

Claims (18)

Radio antenna arrangement for radio connections with terrestrial radio stations for decimeter and / or centimeter waves, with a radiator (3) mounted on the inclined window pane (1) in an electrically conductive vehicle body (10) and at the upper window edge, which consists of a on the outside of the window pane ( 1) attached, projecting from this antenna element (3) and this is attached to a base plate (4) attached to the window pane, with a radiator connection point (2),
characterized by
that the base plate is electrically conductive at least in essential areas and also acts as an electrical counterweight for the radiator (3) and between the radiator (3) and the base plate (4) a radiator connection point (2) is formed, to which a sufficiently thin antenna line (5) is connected is which is led on the window pane (1) to the upper edge of the window pane, is bent there and is guided on the inner surface of the window pane through the window adhesive bead (6) into the interior of the vehicle and next to the radiator (3) for further radio service a patch antenna (7) with patch connection point (8) is attached to the base plate (4) and the patch antenna signal is also routed from the patch connection point either via the same or a further sufficiently thin antenna line (9) which runs on the window pane to the upper edge of the window pane , bent there and on the inner surface of the window pane through the window adhesive Aupe (6) is guided into the interior of the vehicle. Radio antenna arrangement according to claim 1
characterized in that
the radiator (3) is essentially in the form of a vertically oriented rod radiator and the patch antenna (7) is oriented towards the radiator in such a way that the connecting line (18) between the lower radiator end (11) and the center of the patch antenna (7) aligns with the Perpendicular to one of the edges of the patch antenna. Radio antenna arrangement according to claims 1 and 2
characterized in that
A bandpass is connected between the patch antenna connection point (8) and the further antenna line (9), which is only permeable to signals in the reception frequency range of the patch antenna. Radio antenna arrangement according to claims 1 and 2
characterized in that
a low-noise preamplifier (13) is connected between the patch antenna connection (8) and the further antenna line (9) and the power supply to the preamplifier is either routed via the inner conductor of the further antenna line (9) or via an additional, similarly laid line. Radio antenna arrangement according to claim 3
characterized in that
a bandpass is connected between the patch antenna connection point (8) and the further antenna line (9), which is only permeable for signals in the reception frequency range of the patch antenna, which is attached to the base plate and which is followed by a low-noise preamplifier (13), which is also on the Base plate (4) is attached and the power supply of the preamplifier is either routed via the inner conductor of the further antenna line (9) or via an additional, similarly laid line. Radio antenna arrangement according to Claims 1 to 5
characterized in that
to form a group antenna for radio connections with terrestrial radio stations, at least one second radiator (14) with a second radiator connection point (15) is present and the radiator connection points are optionally electrically connected via a network (16) and a group antenna connection point (17) is formed on the base plate (4) to which the antenna line (5) for radio connections with terrestrial radio stations is connected and the patch antenna (7) is arranged in the area between the radiators on the base plate. Radio antenna arrangement according to Claims 1 to 6
characterized in that separate antenna lines are provided for the radio antenna for radio connections with terrestrial radio stations and the antenna for the further radio service and to suppress the edge radiation of the radio antenna, for the terrestrial radio stations in the antenna for the further radio service a bandstop in the signal path between the antenna line (5 ) and radiator (3) is present with blocking effect in the frequency range of the further radio service. Radio antenna arrangement as in claim 7, however
characterized in that a bandstop to protect the radio antenna for radio connections with terrestrial radio stations from the edge radiation of the antenna for the further radio service in the signal path between further antenna line (9) and patch antenna (7) is present. Radio antenna arrangement according to claims 8 and 9
characterized by
that both band stop measures are combined. Radio antenna arrangement according to claims 8 and 9
characterized by
that the base plate may be a multilayer printed circuit and is designed both as an electrical element for the electrical interconnection of the signal paths and as a mechanical support for the electrical components. Radio antenna arrangement according to Claims 1 to 10
characterized by
that the antenna line or the antenna lines as mutually parallel microwave striplines in two-layer technology with a thin conductor over a ground plane or in three-layer technology with two ground planes (24), which are connected at suitable intervals by vias (19) and a thin, between signal-carrying conductors (20) located on these surfaces and all lines are preferably configured as a multiple line in a network. Radio antenna arrangement according to Claims 1 to 10
characterized by
that an antenna line is designed as a coplanar line with a comparatively wide signal-carrying conductor (21) and a wide ground plane (23) for the transmission of large powers. Radio antenna arrangement according to claims 11 and 12
characterized by
that all lines in the network are designed as a thin multiple line in three-layer technology and one of the antenna lines with two outer ground surfaces (24), which are connected at suitable intervals by vias (19) and a signal-carrying between these surfaces, to comply with the wave resistance requirement very much thinly selected conductor (20), and that for the transmission of large powers one of the antenna lines is designed as a coplanar line with a comparatively wide signal-carrying conductor (21) in the middle position of the three-layer arrangement and the two outer conductor layers in the area of the coplanar line are removed however, at intervals which are small in relation to the wavelength, are connected to one another with narrow conductor bridges (22) and the intervals and the width of the conductor bridges (22) are selected such that the wave resistance requirement at the frequency in question is satisfied. Radio antenna arrangement according to claim 13
characterized by
that all lines in the network are designed as a thin multi-line in three-layer technology and one of the antenna lines with the two outer ground surfaces (24) with plated-through holes (19) and a signal-carrying conductor (20) located between these surfaces to meet the wave resistance requirement is very thin and that for the transmission of large powers one of the antenna lines is arranged on one of the edges of the thin multiple line and is designed as a coplanar line or as an asymmetrical coplanar line with a comparatively wide signal-carrying conductor (21) in the middle position of the three-layer arrangement and the two outer conductor layers ( 24) are removed in the area of the coplanar line. Radio antenna arrangement according to Claims 1 to 6
characterized in that separate antenna lines are provided for the radio antenna for radio connections with terrestrial radio stations and the antenna for the further radio service and to suppress the edge radiation of the radio antenna for the terrestrial radio stations into the antenna for the further radio service a bandstop in the signal path between the antenna line (5) and radiator (3) is present with blocking effect in the frequency range of the further radio service. Radio antenna arrangement according to Claims 1 to 15
characterized in that between the patch antenna (7) and the connected further circuit connected a bandstop with blocking effect in the frequency range of the radio antenna for radio connections with terrestrial radio stations to protect against non-linear effects in the signal path of the further radio service. Radio antenna arrangement according to Claims 1 to 16
characterized in that
the radiator (3) or the radiators are designed to form a group antenna for radio connections with terrestrial radio stations and, if necessary, the network for several radio services (eg D-network and E-network and AMPS) and alternatively a signal via the antenna line (5) of the intended terrestrial radio services is transmitted and received. Radio antenna arrangement according to Claims 1 to 17
characterized in that
there is an additional patch antenna for an additional radio service on an additional frequency and the electrical signal path is designed similarly to claims 1 to 17 for the patch antenna for the further radio service.

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