DE19937343A1 - Modular dual band radiator system with azimuthal omni-directional characteristic has two metal plates with circular strip-like conductor between them - Google Patents

Abstract

The radiator system includes a strip-shaped conductor (1) arranged in a closed circle above a circular metal plate (3). The conductor is positioned by spacers (10) made e.g. of PVC. A second circular metal plate (4) is arranged axial-symmetrically over the plane of the conductor and is electrically connected to the plate (3) at the centre via a cylindrical metal connecting element (9). The outer conductor (6.2) of an exciting coaxial waveguide (6) is connected to the edge of a panel (7) within the plate (3). The inner conductor (6.1) of the exciting waveguide is connected to the conductor (1) at an angle of 65 degrees to the position of the connecting element. The connecting element couples the circular conductor to the metal plate (3).

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 generation of a linearly vertically polarized omnidirectional radiation in the azimuthal plane preferably within that for trunked radio or mobile radio services reserved spectral ranges between 410 MHz and 430 MHz so like 450 MHz and 470 MHz. The primary goal here is in particular in the configuration of a spotlight system with an extremely flat design or with a minimal survey of the surface normal of the assembly level. Furthermore, the further goal is to develop a radiator system, the design of which allows the short-term discharge of extremely high currents.

Field of application of the invention

The field of application of the invention relates primarily to the mobile radio area, preferably and primarily on the railway radio area. Here the planar emitter forms a dual-band antenna system for the outdoor mon days or for outboard applications for both landmobile and aircraft as well as for maritime means of transport and transportation, preferably for landmo bile rail vehicles, by means of which preferably the communication users or the communication services of the 70 cm band are supported. In addition, the radiator component according to the invention forms Basic module for short and medium-range transmission systems within commu nication, sensor or security applications.

Characteristic of the known prior art

Known antenna solutions for the field of mobile communication are based on linear antenna designs in the form of monopole arrangements in a shortened form  or unabridged version. These linear antennas are both external mountable on-board antennas as well as directly coupled to the terminal Components known and with different directives and effects degrees afflicted. Flat versions with the property of vertical polarization of the electric field vector as well as the omnidirectional characteristic in the azimuthal plane are based on the ring-slot concept.

Presentation of the nature of the invention

The object of the invention is to configure an extreme miniaturized and flat spotlight component with the property of Generability of a dual-band vertically polarized omnidirectional radiation in the Azimuthal plane of the surface on a dielectric or conductive, preferably a conductive, base or assembly level mountable spotlight with extreme flat height dimensioning.

The object is achieved in that a conductor ( 1 ), preferably in the form of a strip conductor, is circular, elliptical, triangular, rectangular or in a further derived or any geometric shape, preferably circular and closed, or with a capacitive element ( 2 ) is loaded by the geometric band ends of the conductor ( 1 ) with a capacitive element ( 2 ), preferably consisting of two parallel to each other and through a dielectric coating ( 2.2 ) consisting of a loss-minimizing dielectric, preferably consisting From a loss-minimizing and low dielectric film material, preferably carried out in the form of a geometrically defined air gap, galvanically isolated strip conductor surfaces ( 2.1 ), preferably carried out in the form of the geometric extension of the strip conductor ( 1 ). The object is further achieved in that the strip conductor ( 1 ), which is preferably circular and closed, is at a defined distance from a conductive, preferably metallic, plate or film ( 3 ) with a circular, elliptical, triangular, rectangular, square, pentagonal, hexagonal or octagonal, preferably circular, Beran tion is arranged in such a way that the plane ( 5 ) spanned by the circularly joined conductor ( 1 ) extends parallel to the conductive plate or film ( 3 ). Parallel to the conductive plate or foil ( 3 ) or to the plane ( 5 ) and with an identical geometric axis, another conductive, preferably metallic, plate or foil ( 4 ) with circular, elliptical, triangular, rectangular, square, pentagonal, hexagonal or octagonal, preferably circular, and the same or less, preferably less, radius with respect to the diameter of the plate or film ( 3 ) and the same or larger, preferably larger, diameter bezüg Lich the diameter of the annular conductor ( 1 ), whereby the conductive plate or film ( 4 ), preferably with a circular rim, is centric and conductive by means of a conductive connecting element with a circular, elliptical, triangular, square, rectangular, pentagonal or hexagonal cross section, preferably by means of a cylindrical and conductive connecting element ( 9 ), preferably consisting of copper, brass or aluminum, with the conductive plate or foil ( 3 ) connected and the level ( 5 ) through the plates or foils ( 3 ) and ( 4 ) is closed and the plate or foil ( 3 ) is preferably detachably connected galvanically by means of defined screw connections to the preferably conductive basic or assembly level. The electromagnetic excitation takes place by means of a coaxial waveguide ( 6 ), in that the outer conductor ( 6.2 ) of the coaxial waveguide ( 6 ) is connected to the diaphragm edge ( 7 ) within the conductive plate or film ( 3 ) and the inner conductor ( 6.1 ) of the coaxial waveguide ( 6 ) passed centrally through the aperture ( 7 ) within the conductive plate or film ( 3 ) and galvanically coupled, preferably by means of a soldered connection, to the conductor ( 1 ), which is preferably arranged in a ring-shaped manner. The defined geometric extension of the outer conductor ( 6.2 ) through the diaphragm edge ( 7 ) and the specific tapering of the outer and / or inner conductor diameter enables the defined control of the coupling impedance or admittance and thus the input or output impedance profile of the resonator arrangement. The preferably circularly arranged conductor ( 1 ) is connected to the conductive plate or foil ( 3 ) at a defined angular distance from the excitation point, preferably by means of a cylindrical copper, brass or aluminum body ( 8 ), the conductive connecting element ( 8 ) is carried out in closed form or is galvanically separated at one or more positions with respect to the longitudinal axis of the connecting element ( 8 ) and the gap areas delimited by the cross-sectional areas ( 2.1 ) of the conductive connecting element ( 8 ) are provided with a dielectric covering ( 2.2 ), preferably consisting of a loss-minimal dielectric, preferably consisting of a loss-minimal paint low-dielectric film material, the cross-section of the connecting element ( 8 ) axially constant or along the longitudinal axis of the conductive connecting element ( 8 ) continuously or discontinuously I can be dimensioned to be able to specifically control the admittance profile of the connecting element. In the same way, there is the possibility of continuous or discontinuous variation of the substance or susceptibility profile along the longitudinal axis of the connecting element in order to be able to selectively measure the resulting admittance profile via the defined or definable design of the location dependence of the material composition of the connecting element. In this case, the spectral excitation condition of the electromagnetically oscillatable resonator arrangement is determined via the dimensioning of the wiring elements and their location dependencies and thus via the dimensioning of the mutual angular distances or the respectively resulting angular distances between the excitation and short-circuit points. The cross-sectional profile of the conductor ( 1 ) can be dimensioned both rectangular and circular, elliptical, triangular or square. In the same way, there is the possibility of variable arrangement of the wide or narrow sides or the axes of the conductor profile with respect to the surface normal of the conductive plates or foils ( 3 ) and ( 4 ). The positioning of the conductor ( 1 ) over the conductive plate or film ( 3 ) is carried out by means of dielectric, preferably cylindrical, spacer elements ( 10 ), preferably consisting of polyvinyl chloride.

The radiator arrangement can be wired with additional external complex load elements, which can each be synthesized in the form of concentrated circuit elements or in the form of distributed parameters, the structure of the capacitive arrangement ( 2 ) being connected to a coupling path between the conductor ( 1 ) and the conductive plate or film ( 3 ) or between the conductor ( 1 ) and the conductive plate or film ( 4 ) or between the conductor ( 1 ) and the conductive plates or films ( 3 ) and ( 4 ) with an identical or non-identical coupling point with respect to the conductor ( 1 ) or can only be transferred between the conductive plates or foils ( 3 ) and ( 4 ).

Embodiment

The arrangement according to the invention is intended to be explained in more detail using an exemplary embodiment are explained.

According to the illustration, a band-shaped conductor ( 1 ) is arranged in a circular shape and is closed axially symmetrically over a circular metallic plate ( 3 ) by the circularly shaped conductor ( 1 ) by means of the spacer elements ( 10 ), consisting of polyvinyl chloride, above the metallic plate ( 3 ) is positioned. Above the level of the ring-shaped conductor ( 1 ), a second circular metallic plate ( 4 ) is arranged axially symmetrically, which is galvanically connected to the plate ( 3 ) in the center via a cylindrical and metallic connecting element ( 9 ) as shown in the figure. The outer conductor ( 6.2 ) of the exciting coaxial waveguide ( 6 ) is galvanically connected to the edge of the diaphragm ( 7 ) within the plate ( 3 ). The centrally guided inner conductor (6.1) of the exciting waveguide galvanic cally connected as illustrated in an angular distance of 65 degrees of angle from the position of the conductive and cylinder-shaped connecting element (8) with the conductor (1), wherein the connecting element (8) the annular trained conductor ( 1 ) and the metallic plate ( 3 ) galvanically coupled together.

Claims (2)

1. Modular dual-band radiator system with azimuthal omnidirectional characteristics, consisting of an arrangement of geometrically defined conductive levels, characterized in that

• - Two conductive plates or foils ( 3 ), ( 4 ) are arranged at a defined distance parallel to each other by the plate or foil ( 3 ) formed with a circular border and the conductive plate or film ( 4 ) formed with a circular border are dimensioned, the plates or foils ( 3 ), ( 4 ) having the same or different outside diameter, preferably different outside diameter, and the circular plates or foils ( 3 ), ( 4 ) being arranged axially symmetrically to one another;
• - The conductive plates or foils ( 3 ), ( 4 ) are galvanically coupled in their respective apex axis with a conductive connecting element ( 9 ), the conductive connecting element with a circular, elliptical, triangular, square, rectangular, pentagonal or hexagonal, preferred wise circular, cross-section is formed;
• - Between the levels of the conductive plates or foils ( 3 ), ( 4 ) an annularly shaped conductor level ( 1 ) parallel to the surface and axially symmetrical is added;
• - The ring-shaped conductor ( 1 ) is closed or the ring-shaped conductor is galvanically separated at one or more positions of the ring and the gap areas defined by the cross-sectional areas ( 2.1 ) of the conductor ( 1 ) with a dielectric covering ( 2.2 ) from a loss-minimal dielectric, preferably consisting of a loss-minimal and low-dielectric film material;
• - The ring-shaped conductor ( 1 ) is galvanically connected via a conductive connecting element ( 8 ) or several conductive connecting elements ( 8 ) with the conductive plate or film ( 3 ), the conductive connecting element ( 8 ) or the conductive connecting elements ( 8 ) with a circular, elliptical, triangular, square, rectangular, pentagona len or hexagonal, preferably circular, cross section is or are formed;
• - The conductive connecting elements ( 8 ) are closed or galvanically separated at one or more positions and the gap areas through the cross-sectional areas ( 2.1 ) of the conductive connecting element ( 8 ) delimited areas each with a dielectric covering ( 2.2 ), preferably consisting of a minimum loss Dielectric, preferably consisting of a low-loss, low-dielectric film material;
• - The annular conductor ( 1 ) with a coaxial waveguide ( 6 ) is coupled by the inner conductor ( 6.1 ) of the coaxial waveguide ( 6 ) in a defined th angular distance relative to the position of the axis of the conductive connecting element ( 8 ) conductive with the annular Conductor ( 1 ) and the outer conductor ( 6.2 ) of the same coaxial waveguide ( 6 ) are conductively connected to the plate or film ( 3 ), the outer conductor ( 6.2 ) passing through the aperture ( 8 ) of the plate or film ( 3 ) the space delimited by the circular plates or foils ( 3 ), ( 4 ) is limited in such a way that the space in the arrangement space delimited by the plates or foils ( 3 ) and ( 4 ) bilaterally orthogonally with respect to its axis is the outer conductor segment does not touch the ring-shaped conductor ( 1 ) and is continuous or discontinuous with respect to the inside and outside diameter I'm being taped.

2. Modular dual-band radiator system with azimuthal omnidirectional characteristic according to claim 1, characterized in that the conductor ( 1 ) and the conductive plate or film ( 3 ) or the conductor ( 1 ) and the conductive plate or film ( 4 ) or the conductor ( 1 ) and the conductive plates or foils ( 3 ) and ( 4 ) with identical or non-identical coupling point with respect to the conductor ( 1 ) or exclusively the conductive plates or foils ( 3 ) and ( 4 ) each punctually by means of complex loading elements, each in Form concentrated circuit elements or synthesized in the form of distributed parameters are coupled.