DE19940470A1 - Multi-band radiator system with sector characteristic e.g. for mobile radio and mobile navigation applications, has ring-shaped plates or foils coupled by capacitive loading element - Google Patents

Abstract

A hybrid or combined arrangement for multi-band radiator system i.e. with dual radiation function, such as two-meter band/GPS, with noise adaptive signal amplifier arranged within the antenna housing, includes two conductive plates or foils (1,2) spaced apart from each other and coupled to a coaxial wave-guide (5), in which the inner conductor is joined to the ring-shaped plate or foil (1) and the outer conductor (5.2) of the coaxial wave-guide. The ring-shaped plate or foil (1) is coupled via a capacitive loading element (3) or a multi-pair capacitive loading element in the form of concentric functional elements or in the form of wave-guide elements with distributed parameters. The dielectric plate or foil as well as the carrier and the functional components of a large area resonator (10) are designed according to slot line- or microstrip line-technology.

Description

Aim of the invention

The aim of the invention is to configure an extremely miniaturized th and primarily extensive antenna system with the Eigen the ability to generate a linearly polarized sector radiation within a Spatial hemisphere, preferably within the bidirecti for satellite-based onal information transmission reserved spectral ranges between 137 MHz and 138 MHz or 148 MHz and 15 MHz (RX: 137 MHz - 138 MHz / TX: 148 MHz - 150 MHz) and the property of the producibility of a right rotating circularly polarized and coordinate-wide sector radiation the main radiation direction parallel to the surface normal of the arrangement.

The aim of the invention is, in particular, the two radiation functions NEN - 2 meter band / GPS - to assign a hybrid or combination arrangement NEN and the GPS antenna component with a within the antenna con Taimnents integrated noise-matched signal amplifier to couple.

Field of application of the invention

The field of application of the invention relates primarily to the mobile radio area and the area of mobile navigation by means of reception or the evaluation of the GPS signals. The planar antenna forms an antenna component for external installation or for outboard applications both for landmobile and aircraft as well as for maritime movement and traffic means by means of which preferably the satellite-based communication applications or the satellite-based communication services of the 2-meter Band are supported.

In addition, the spotlight system according to the invention forms a basismo dul for satellite-based transmission systems within communication, sen safety 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.

Known antenna solutions for receiving the GPS signals are based on Helical antenna designs and resonator antenna designs in micro strip technology, both low-dielectric structure supports in the form of Polytetrafluoroethylene compositions as well as high dielectric structure supports in Form of electrically high-quality ceramics are used as structural supports.

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 linearly polarized sector radiation on a surface dielectric or conductive base plane mountable radiator and one circularly offset with respect to the frequency range of the omnidirectional radiation polarized sector radiation with the radiation maximum in the direction of Surface normal of the emitter or in the direction of the emitter axis.

The object is achieved according to the invention in that a conductor ( 1 ), preferably in the form of a strip conductor, has its geometric strip ends with a capacitive element ( 2 ), preferably consisting of two parallel to one another and by a dielectric coating ( 3.3 ), Consisting of a loss-minimal dielectric, preferably consisting of a loss-minimal and low-dielectric film material, preferably carried out in the form of a geometrically defined air gap, galvanically isolated strip conductor surfaces ( 3.1 , 3.2 ), preferably carried out in the form of the geometric lengthening of the strip conductor ( 1 ), in a ring , elliptical, triangular, quite angular or in a further derived or any geometric shape, preferably circular, is arranged, the capacitive element ( 3 ) being substituted by two conductive plates with circular, elliptical, triangular, Vierec kiger, pentagonal, hexagonal or octagonal edging of the conductive plates ( 3.1 ), ( 3.2 ) or the enclosed dielectric covering ( 3.3 ) can be formed or a conductor ( 1 ) circularly in a defined distance and preferably parallel to the surface over a circular, elliptical, triangular, square, rectangular, pentagonal, hexagonal or octagonal, preferably circular, conductive plate or film ( 2 ), the area dimension, preferably its diameter, equal to the outer diameter or larger than the outer diameter, preferably larger than the outer diameter, the ring-shaped conductor ( 1 ) is dimensioned, arranged and subjected to selective capacitive loading by one or more capacitive blind elements ( 3 ) and / or ohmic loading elements ( 4 ) between the conductor ( 1 ) and the conductive plate or foil ( 2 ) and / or complex loading elements ( 14 ) with so capacitive / inductive as well as ohmic components in the form of concentrated functional elements or in the form of waveguide elements with distributed parameters can be coupled in a defined location, distance or angle. The electromagnetic excitation takes place by means of a coaxial waveguide ( 5 ) in that the inner conductor ( 5.1 ) of the coaxial waveguide ( 5 ) with a defined angular offset with respect to the respective positioning location of the capacitive elements ( 3 ) and / or the ohmic coupling elements ( 4 ) and / or the complex loading elements ( 14 ) is galvanically coupled with the preferably circularly shaped conductor ( 1 ) and the outer conductor ( 5.2 ) of the coaxial waveguide ( 5 ) is galvanically with the diaphragm edge of the preferably circularly designed diaphragm ( 6 ) within the conductive plate or film ( 2 ) is connected, the axis of the coaxial waveguide ( 5 ) being guided parallel to the surface normal of the plane ( 7 ) spanned by the preferably circular conductor ( 1 ) and axially symmetrically through the preferably circular aperture ( 6 ). The outer conductor ( 5.2 ) is limited in the plane of the conductive plate or film ( 2 ) or is axially symmetrical through the diaphragm ( 6 ) with unchanged or continuously or discontinuously tapered inside and / or outside diameter, preferably unchanged inside diameter and changed outside diameter, passed so that a defined capacitance is generated between the preferably circular ring-shaped conductor ( 1 ) and the end edge area of the outer conductor ( 5.2 ). The ohmic load elements ( 4 ) are preferably designed as low-resistance load elements, preferably as low-resistance resistors or conductive coupling elements with high conductivity losses. The capacitive loading elements ( 3 ) are preferably as conductive coupling elements, the ends of which, with the inclusion of a dielectric covering, defined covering geometry and defined dielectric properties, as well as the conductor surface of the conductor ( 1 ) and / or the conductive plate or film ( 2 ), are a capacitive element capacitive component is determined by the geometry of the respective coupling element, the respective resulting gap geometry and the susceptibility of the dielectric covering and its transformer component is formed on the location-dependent coupling level of the capacitive loading element.

According to the invention, a dielectric plate ( 8 ) with a hexagonal edge, the surface ( 9 ) facing the plane ( 2 ) of which is conductively coated and the one of which is coated in a plane-parallel and axially symmetrical manner to the plane ( 7 ), which is spanned by the preferably circularly arranged conductor ( 1 ) Level ( 2 ) facing surface ( 10 ) is structured in such a way by means of conductive surface elements that the dielectric plate ( 8 ) supports both the carrier and the functional component of a planar resonator in microstrip technology ( 10 ) with spatially orthogonal or temporally offset excitation and a noise-adapted single-stage signal amplifier ( 11 ) in shielded microstrip technology or asymmetrical triplate technology forms, in the same or different, preferably unequal and greater, height with respect to the plane ( 7 ) by means of dielectric spacing elements of any contour, preferably cylindrical spacer elements ( 12.2 ), consisting of Polyvinyl chloride, the radius of the circle comprising the hexagon ( 8 ) being smaller than the inner radius of the strip conductor ( 1 ), which is preferably arranged in a ring.

Embodiment

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

According to the exemplary arrangement shown, an annular conductor ( 1 ), preferably consisting of copper, brass or aluminum, is plane-parallel and at a defined height and axially symmetrical over a circular metallic plate or foil ( 2 ), preferably consisting of copper, brass or aluminum. Here, the plane-parallel mechanical connection between the circular conductor ( 1 ) and the conductive plate or film ( 2 ) takes place via two cylinder-shaped spacer elements ( 12.1 ), preferably consisting of polyvinyl chloride, and via two cylindrical metallic connecting elements ( 3.1 ), each on one side , preferably on the level ( 1 ) facing surface, galvanically connected to the conductive plate or film ( 2 ) and on the opposite surface with a dielectric coating ( 3.3 ), preferably a loss-minimizing and low-dielectric film, covered and only dielectric Connecting elements are mechanically connected to the circular conductor ( 1 ), preferably consisting of copper, brass or aluminum, the conductive connecting elements ( 3.1 ) being mounted with the mutual angular difference shown in the illustration by means of screw, rivet or solder connection be recognized. The electromagnetic excitation of the radiator arrangement takes place via a coaxial waveguide ( 5 ) by galvanically connecting the outer conductor ( 5.2 ) to the edge of the diaphragm ( 6 ) and defining it geometrically while maintaining the diameter ratio of the waveguide ( 5 ) and spatially orthogonal guidance of the waveguide axis is extended with respect to the plane ( 1 ) or ( 2 ) and which is electrically connected to the annular conductor ( 1 ) by means of a dielectric socket ( 5.3 ), preferably consisting of polytetrafluoroethylene, centrally guided inner conductor ( 5.1 ). A concentrated ohmic load element ( 4 ), preferably a concentrated low-ohmic resistance, is positioned at the angular distance to the location of the waveguide coupling as shown in the figure. The exemplary radiator arrangement is further supplemented in such a way that a dielectric plate ( 8 ) with circular, square or hexagonal, preferably hexagonal, edges is plane-parallel and axially symmetrical to the plane ( 7 ), which is spanned by the circularly shaped strip conductor ( 1 ) , whose plane ( 2 ) facing surface ( 9 ) is conductive, preferably by means of a thick homogeneous copper layer, coated and whose plane ( 2 ) facing surface ( 10 ) is structured in such a way by means of conductive, preferably copper, surface elements that the dielectric Plate ( 8 ) forms both the structural support and the functional component of a planar resonator using microstrip technology ( 10 ) with spatially orthogonal or temporally offset excitation as well as a noise-adapted one-stage signal amplifier ( 11 ) using shielded microstrip technology, using dielectric and cylindrical spacing elements e ( 12.2 ), consisting of polyvinyl chloride, is positioned, the shield ( 13 ) being galvanically coupled to the conductive coating ( 9 ) of the dielectric plate ( 8 ) by means of punctual plated-through holes.

Claims (2)

1. Multi-band radiator system with sector characteristic, consisting of an arrangement of geometrically defined and conductive and dielectric levels, characterized in that

• - Two conductive plates or foils ( 1 ), ( 2 ) can be arranged parallel to one another at a defined distance by forming the plate or foil ( 2 ) with a preferably circular border and the conductive plate or foil ( 1 ) with a preferably circular one Boundary who who, the plates or foils ( 1 ), ( 2 ) are dimensioned with a different outer diameter and the circular plate or foil ( 1 ) with a smaller outer diameter than the diameter of the plate or foil ( 2 ) is executed;
• - The circular plate or film ( 1 ) is coupled to a coaxial waveguide ( 5 ) by the inner conductor ( 5.1 ) of the coaxial waveguide conductive with the annular plate or film ( 1 ) and the outer conductor ( 5.2 ) of the coaxial waveguide conductive with the Plate or film ( 2 ) are connected, the outer conductor ( 5.2 ) through the panel ( 6 ) of the plate or film ( 2 ) continuously into the space ( 15 ) between the annular plate or film ( 1 ) and the plate or film ( 2 ) is lengthened in such a way that the outer conductor segment inserted into the interspace of the plates or foils ( 1 ) and ( 2 ) does not touch the plate or foil ( 1 ) and with respect to the inner and outer diameter continuously or discontinuously, preferably discontinuous, is taped;
• - The annular plate or film ( 1 ) via a capacitive element ( 3 ) or one or more pairs of capacitive load elements ( 3 ) in the form of concentrated functional elements or in the form of waveguide elements with distributed parameters of defined reactance and in the case of one or more pairs capacitive loading elements at a defined angular distance from each other and at the same or different, preferably the same, angular distance to the coupling point of the inner conductor ( 5.1 ) with the conductive and preferably circular plate or film ( 1 ) is coupled, that the two coupling points of the or capacitive loading elements ( 3 ) are positioned on an axis parallel to the surface normal of the two surfaces;
• - The capacitive loading elements ( 3 ) are preferably generated in such a way that a conductive body ( 3.1 ) with two opposite and parallel circular, triangular, square, rectangular, penatgonal, hexagona len or octagonal, preferably circular, base surfaces on one side with galvanic the conductive plate or foil ( 2 ) or one-sidedly galvanically connected to the conductor ( 1 ) and the opposite surface is covered with a dielectric foil ( 3.3 ) with a minimum dielectric loss angle and parallel to the surface of the conductor ( 1 ) or the conductive plate or foil ( 2 ) is positioned or coated on both sides with a dielectric film ( 3.3 ) and the two parallel surfaces of the conductive, preferably cylindrical, body ( 3.1 ) parallel to both the conductor ( 1 ) and the conductive plate or film ( 2 ) be arranged;
• - The annular plate or film ( 1 ) via an ohmic resistor ( 4 ) or one or more pair of ohmic resistors ( 4 ) defined impedance, preferably low impedance before, and in the case of single or multi-pair ohmic resistors at a defined angular distance from each other and at the same or different, preferably the same, angular distance to the coupling point of the inner conductor ( 5.1 ) with the conductive plate or film ( 1 ) is coupled in such a way that the two coupling points of the or the ohmic resistances on a parallel to the surface normal of the two Surface axis are positioned, the coupling point (s) of the ohmic resistors ( 4 ) with respect to the radial positioning being preferably arranged on the outer edge of the annular plate or film ( 1 );
• - Plane-parallel and axially symmetrical to the conductive plate or film ( 1 ) a dielectric plate or film ( 8 ) with circular, square, hexagonal or octagonal border, preferably hexagonal border, the surface of the plate or film ( 2 ) facing ( 9 ) coated and conductive the conductive plate or foil (2) facing away from surface (10) is such patterned by leitfähi ger surface elements, that the dielectric plate or sheet (8), both the carrier and the functional component of a surface resonator (10) in slotline or microstrip technology, preferably Microstrip technology, with spatially orthogonal or temporally offset excitation as well as a noise-adapted one- or multi-stage, preferably single-stage, signal amplifier ( 11 ) in shielded microstrip technology or symmetrical or asymmetrical triplate technology, preferably shielded microstrip technology, forms, in the same o the unequal, preferably the same, height is arranged with respect to the conductive annular plate or foil ( 1 ), the radius of the dielectric plate or foil ( 8 ) or the radius of the square ( 8 ) or of the hexagon ( 8 ) or that Circle sized octagon ( 8 ) smaller than the inner radius of the annular conductive plate or film ( 1 ) and the shield ( 13 ) galvanically coupled to the conductive coating ( 9 ) of the dielectric plate ( 8 ).

2. Multi-band radiator system with sector characterization according to claim 1, characterized in that the ohmic resistors ( 4 ) defined impedance, before preferably low-impedance impedance, defined by conductive connecting elements defined conductivity losses and defined geometry, preferably connec tion elements with cylindrical geometry, or by connecting elements consisting of lossy magnetic substances or substance compositions with a static or electrically controllable susceptibility profile can be replaced by inserting them at the respective identical geometric location of the resistors or the resistor to be substituted or at non-identical positions or at a non-identical position.