DE19822398A1 - Miniature sector radiator for motor vehicle antenna - Google Patents

Abstract

The miniature sector radiator consists of an arrangement of geometrically defined and conductive layers. Dielectric inclusions or discontinuities (9) are formed between conductive plates or films. The arrangement is coupled to a coaxial waveguide. The coupling location between the inner conductor of the coaxial waveguide and the conductive plate or film is on a line of symmetry on which the dielectric inclusions are positioned

Description

Aim of the invention

The aim of the invention is to configure an extremely miniaturi based and in the first place extensive antenna component with the Property of the producibility of a linearly polarized and coordinate side broad sector radiation in both the horizontal and vertical planes preferably in the spectral ranges between 890 MHz and 960 MHz as well between 1710 MHz and 1 MHz. Furthermore, the aim of the invention is in the development of a planar emitter arrangement with a pronounced rear radiation attenuation and thus useful radiation only within one Spatial hemisphere, so that in particular for the field of vehicle applications an antenna component arises, which it attaches to the antenna on the glazed surfaces of the vehicle allows the passenger compartment from the Hiding the radiation space of the emitter and hereby the electromagnetic Radiation exposure of the user to known antenna solutions for to minimize this area. The invention further pursues the aim of Immediate installation of the planar spotlight on the glazed surfaces and thus the concept or dimensioning aspect beforehand consideration of the electromagnetically relevant properties of the antenna module spatially upstream dielectric layers or rooms, preferred of the corresponding glazing of the passenger compartment.

In addition, the subject invention pursues the goal of configuration a radiator module, which with minimal modification of the basic structure Possibility of generating both a wide, sector-shaped horizontal and Vertical diagram as well as the generation of an azimuthal omnidirectional slide permits.

The aim of the invention is also to configure the Planar emitter required dielectric structure support through use only electrically conductive and self-supporting thin plates, preferred wise metallic plates or foils to replace and by the use of dielectric base materials with a deviation from the evacuated space  Geometric shortening due to the corresponding dielectric constant by means of distributed capacitive structural elements.

Field of application of the invention

The field of application of the invention relates primarily to the mobile Radio area within the cellular GSM network and the cellular DCS network. The planar antenna forms an optional antenna component or replacement component of the vehicle external antenna with the mounting option inside the passenger compartment. The application relates further area on general indoor applications by adding the spotlight component forms a spatially separate component from the respective terminal and on the concerned room glazing is installed inside and flat.

The radiator component can be used advantageously in cases where the space located to the rear of the antenna aperture is radiation-free or radiation-free kept poor and thus the electromagnetic radiation exposure of the user should be minimized.

In addition, the antenna component is an add-on version for indoor as well as for outdoor applications, preferably in the vehicle area the omnidirectional characteristic can be used.

In addition, the radiator component according to the invention forms Basic module for short or medium-range transmission systems for commun cation, sensor or safety applications.

Characteristic of the known prior art

Known antenna solutions for the field of mobile radio applications are based on linear antenna designs in the form of monopole arrangements in shortened or unabridged version. These linear antennas are both as externally mountable on-board antennas as well as directly with the end device coupled components known and with different directives and Efficiency afflicted, these components from in the azimuthal plane are finally omnidirectional. Known flat antenna solutions are based on two-dimensional, dipole-like configurations, their directional diagram irregular and in connection with the respective subsurface the characteristics have a significant radiation field deformation. The one on the users Radiation properties related to the range are those of the classic Linear antennas clearly inferior. Likewise are targeted hiding properties of the radiation diagram not detectable. Likewise are no solutions known, their electromagnetic or radiation properties  based on asymmetrical and open waveguide techniques, in particular microstrip technology, using self-supporting conductive foil conductors or foil-like guide surfaces can be achieved.

The electrical and usage properties of known antenna solutions exclude the achievement of the objectives of the present invention, so that with the subject invention for the named fields of application applicable technology is expanded compared to the known prior art.

Presentation of the nature of the invention

The inventive task is to configure an extremely mini Aturized and flat spotlight component with the property of Generability of a linearly polarized and spatially wide sector radiation both in the horizontal and vertical planes as well as one characterized retroreflective attenuation and thus useful radiation only within a spatial hemisphere, preferably in the spectral ranges between 890 MHz and 960 MHz or 1710 MHz and 1880 MHz.

The object is achieved in that two conductive plates or foils ( 1 ), ( 2 ) are arranged at a defined distance parallel to one another, the conductive plate or foil ( 1 ) having a square, hexagonal or circular border, preferably one circular border, formed and the function of a ground surface fulfilled and the conductive plate or film ( 2 ) is also formed with a square, hexagonal or circular border, preferably a circular border, with the conductive plates or films ( 1 ), ( 2 ) with identical or different diameters, preferably different diameters, and the conductive plate or foil ( 2 ) with a smaller diameter than the conductive plate or foil ( 1 ).

According to the invention, the object is further achieved in that the two conductive plates or foils ( 1 ), ( 2 ) are arranged one above the other at the intersection of the surface diagonal or centrally symmetrical and plane-parallel and at the intersection of the surface diagonals or in the center ( 3 ) of the conductive plates or foils ( 1 ), ( 2 ) by means of a conductive cylinder or cylinder, preferably cylinder ( 4 ), are connected, the conductive connections between the plate or foil ( 1 ) and the conductive cylinder ( 4 ) and between the conductive Plate or film ( 2 ) and the conductive cylinder ( 4 ) are preferably designed as a screw, rivet or solder connection.

The arrangement according to the invention is coupled to a coaxial waveguide by the inner conductor ( 6 ) of the coaxial waveguide being conductively connected to the conductive plate or film ( 2 ) and the outer conductor ( 7 ) of the coaxial waveguide being conductively connected to the conductive plate or film ( 1 ) are connected, the outer conductor ( 7 ) in the plane of the diaphragm ( 8 ) being conductively coupled to the diaphragm edge of the conductive plate or film ( 2 ) or through the diaphragm ( 8 ) of the conductive plate or film ( 1 ) passing through into the Space ( 5 ) between the conductive plates or foils ( 1 ), ( 2 ) is extended in such a way that the outer conductor segment introduced into the space ( 5 ) of the conductive plates or foils ( 1 ), ( 2 ) extends the conductive plate or film ( 2 ) is not touched and is taped continuously or discontinuously with respect to the inside and outside diameter, whereby the defined dimensioning the length and diameter ratios as well as the position of the coupling point ( 10 ) between the inner conductor ( 6 ) and the conductive plate or film ( 2 ) there is the possibility of specifically determining or influencing the input impedance profile of the radiator arrangement.

In addition to the geometry-side dimensioning of the conductive plates ( 1 ), ( 2 ) and their mutual distance, the vibration condition and the input impedance profile of the resonator arrangement are determined by means of one or more dielectric inclusions ( 9 ), preferably by means of a dielectric inclusion, which or between the Conductive plates ( 1 ) and ( 2 ) are introduced and preferably on the line of symmetry of the arrangement, which is preferably identical to the radial line on which the coupling point ( 10 ) between the inner conductor ( 6 ) and the conductive plate or film ( 2 ) is positioned, or will be, wherein the two plane-parallel and opposite base surfaces of the dielectric inclusions are square, rectangular, pentagonal, hexagonal, circular or elliptical, preferably circular. In addition to the material composition or the susceptibility profile of the discontinuities, the determining variables are the contour and size of the surfaces resting on the conductive plates or foils ( 1 ), ( 2 ), which are determined by the mutual distance between the conductive plates or foils ( 1 ), ( 2 ) primary fixed geometric height of the dielectric inclusion or discontinuity and the respective position of the inclusion.

Embodiment

The subject invention is intended to be used by means of suitable exemplary embodiments for the frequency range between 890 MHz and 960 MHz are explained in more detail. Here, by means of the exemplary arrangements within the above Spectral range a linearly polarized radiation field with sector-shaped Radiation diagram and radiation maximum in the direction of the surface normal the arrangement.

According to Fig. 1 is a conductive metallic plate ( 1 ) with a circular border and the diameter of 87 mm, preferably consisting of copper, brass or aluminum, via a conductive socket ( 4 ), preferably consisting of copper, brass or aluminum , with a second conductive metallic plate ( 2 ) with a circular border and the diameter of 76 mm connected in such a way that the conductive socket ( 4 ) is positioned at the center ( 3 ) of the plates ( 1 ), ( 2 ) and thus the plates ( 1 ) and ( 2 ) are arranged symmetrically and plane-parallel to each other and with a mutual distance of 6.75 mm.

The galvanic coupling of the inner conductor ( 6 ) of the coupling coaxial waveguide takes place with the conductive plate ( 2 ) at point ( 10 ). Here, the inner conductor is guided centrally by means of a dielectric socket ( 7 ) with a minimum dielectric loss angle, preferably a PTFE socket, through the aperture ( 8 ) within the conductive plate ( 1 ) to the conductive plate ( 2 ). The PTFE bushing is designed as a cylinder jacket with a length of 8 + 0.2 mm, the outside diameter of which is 3.8 + 0.05 mm and the inside diameter of 1.2 + 0.05 mm. The outer conductor of the signal-coupling coaxial waveguide is end-coupled with the diaphragm edge of the diaphragm ( 8 ) within the surface parallel to the plate ( 2 ) arranged conductive plate ( 1 ) in the diaphragm plane of the diaphragm ( 8 ).

According to Fig. 2, a conductive metallic plate ( 1 ) with a circular rim and a diameter of 90 mm, preferably consisting of copper, brass or aluminum, via a conductive socket ( 4 ), preferably consisting of copper, brass or aluminum, connected to a second conductive metallic plate ( 2 ) with a circular border and a diameter of 76 mm in such a way that the conductive socket ( 4 ) is positioned at the center ( 3 ) of the plates ( 1 ), ( 2 ) and thus the plates ( 1 ) and ( 2 ) are arranged symmetrically and plane-parallel to each other and with a mutual distance of 5.8 mm. At a distance of 19-0.1 mm, measured from the center ( 3 ) of the arrangement, and on the line of symmetry of the arrangement, a cylindrical dielectric body ( 9 ) consisting of polyvinyl chloride, with a diameter of 15 + 0.5 mm and a height of 5.8-0.05 mm between the conductive plates ( 1 ) and ( 2 ) positioned and inserted.

The galvanic coupling of the inner conductor ( 6 ) of the coupling coaxial waveguide takes place with the conductive plate ( 2 ) at point ( 10 ). Here, the inner conductor is guided by means of a dielectric socket ( 7 ), preferably a PTFE socket, through the diaphragm ( 8 ) within the conductive plate ( 1 ) to the conductive plate ( 2 ). The PTFE bushing is designed as a cylinder jacket with a length of 6.8 + 0.1 mm, the outside diameter of which is 3.8 + 0.05 mm and the inside diameter of 1.2 + 0.05 mm. The outer conductor of the signal-coupling coaxial waveguide is finally coupled to the diaphragm edge of the diaphragm ( 8 ) within the conductive plate ( 1 ) arranged parallel to the surface of the plate ( 2 ) in the diaphragm plane of the diaphragm ( 8 ).

By means of the following exemplary arrangement within the spectral spectrum a linearly polarized radiation ranges between 1710 MHz and 1890 MHz field with sector-shaped radiation diagram and radiation maximum in Direction of the surface normal of the arrangement shown.  

According to Fig. 3 is a conductive metallic plate ( 1 ) with a circular edge and the diameter of 87 mm, preferably consisting of copper, brass or aluminum, via a cylindrical dielectric socket ( 9 ) consisting of polyvinyl chloride, with a second conductive metallic plate ( 2 ), the area of which corresponds to the complement of a circular area reduced by two identical opposite circular section areas, coupled parallel to the surface, the center ( 3 ) of the circular plate ( 1 ) and the intersection of the lines of symmetry of the conductive plate ( 2 ) being positioned congruently one above the other or be arranged on an identical axis parallel to the direction of the surface normal.

The galvanic coupling of the inner conductor ( 6 ) of the coupling coaxial waveguide takes place with the conductive plate ( 2 ) at point ( 10 ). Here, the inner conductor by means of the dielectric socket ( 7 ), preferably consisting of PTFE, is guided centrally through the diaphragm ( 8 ) within the conductive plate ( 1 ) to the conductive plate ( 2 ). The outer conductor of the signal-coupling coaxial waveguide is finally coupled to the diaphragm edge of the diaphragm ( 8 ) within the conductive plate ( 1 ) arranged parallel to the surface of the plate ( 2 ) in the diaphragm plane of the diaphragm ( 8 ).

Claims (2)

1. Miniature sector heater, consisting of an arrangement of geometrically defi ned and conductive layers, characterized in that

• - Two conductive plates or foils are arranged at a defined distance parallel to one another by forming the conductive plate or foil ( 1 ) with a circular border and the conductive plate or foil ( 2 ) is also formed with a circular border, the conductive The plate or film ( 1 ) and the conductive plate or film ( 2 ) are conductively connected via a centrally symmetrically arranged conductive cylinder or cylinder jacket ( 4 ) and the diameters of the conductive plates or films ( 1 ), ( 2 ) are different or identical, preferably different, be formed;
• - Between the conductive plates or foils ( 1 ), ( 2 ) and on the line of symmetry of the arrangement one or more dielectric inclusions or discontinuities ( 9 ), preferably a dielectric inclusion, are introduced or will, the two plane-parallel and opposite basic surfaces of the dielectric inclusions are formed square, rectangular, pentagonal, hexagonal, circular or elliptical, preferably circular;
• - The arrangement is coupled to a coaxial waveguide by the inner conductor ( 6 ) of the coaxial waveguide at the coupling location ( 10 ) being conductively connected to the circular plate or film ( 2 ) and the outer conductor of the coaxial waveguide being conductively connected to the circular plate or film ( 1 ) is connected, the inner conductor of the coaxial waveguide being guided through a circular aperture ( 8 ), which is designed as a circular opening within the circular plate or film ( 1 ), axially symmetrical to the aperture boundary and without a galvanic connection to it;
• - The coupling location between the inner conductor ( 6 ) of the coaxial waveguide with the conductive plate or film ( 2 ) on one of the line of symmetry on which the dielectric inclusions ( 9 ) or the dielectric inclusion ( 9 ) are positioned or will be identical radial line the conductive plate or film ( 2 ) is set.

2. Miniature sector radiator according to claim 1, characterized in that the plane-parallel and symmetrically arranged conductive plates or foils ( 1 ) and ( 2 ) center symmetrically via an ohmic resistance, preferably as a low resistance, are connected to each other.