DE3309405A1 - Receiving antenna for very-high frequencies - Google Patents

Abstract

In order to increase the bandwidth and to reduce the structural heights in a receiving antenna for very-high frequencies which is constructed in the manner of a coaxial antenna, especially for microphone signals which are transmitted by wireless means, it is proposed to fit two ferrite sections, having different 1/d ratios and an essentially low permeability, isolated from one another between the two metal tube sections. One of the two ferrite sections is surrounded by the coil windings of two associated LC resonant circuits which have different centre frequencies and are essentially not coupled to one another. Furthermore, the LC resonant circuits are in each case connected, via an associated decoupling coil, to a transformer which is connected to the coaxial connecting cable, which transformer transforms the overall impedances of the antenna, which are effective in the decoupling coils, to the characteristic impedance of the connecting cable, and carries out the reversal in balancing.

Description

RECEIVING ANTENNA FOR ULTRA SHORT WAVES

DESCRIPTION The invention relates to a receiving antenna according to the preamble of claim 1.

As resonance antennas for receiving ultrashort waves is occasionally the so-called coaxial antenna (called sleeve antenna in English-speaking countries) used (Karl Rothammel "Antennenbuch, Telekosmos-Verlag, Franckh'sche Verlagsbuchhandlung, Stuttgart, 1973, page 302), which is one of two superimposed and has half-wave dipole insulated from each other, the ¼ tubes attached to an insulated support. Through the lower S / 4 pipe is a coaxial Connection cable led to the central feed point between the two A / 4 pipes. The inner conductor of the connection cable is connected to the lower end of the upper 1/4 tube electrically connected, while the outer conductor of the connecting cable with the upper Electrically connected end of the lower X / 4 tube. The lower 1/4 tube represents represents a dipole half and forms at the same time together with the one running in it Section of the connecting cable a quarter-wave blocking pot, whereby Mantle waves on the connecting cable are suppressed. The band limit of the known Coaxial antenna transmittable frequency band is determined by the diameter of the ¼ tubes determined, so that - as is the case with all stretched A / 2 dipoles - a relative narrow-band impedance curve results, which can be achieved by choosing a reasonably larger one The diameter of large antennas can only be improved within certain limits.

As receiving antennas, especially for portable radio receivers, magnetic antennas are also known (F.

Vilbig "Textbook of High Frequency Technology", 5 edition, Academic Verlagsgesellschaft Geest and Portig K.-G., Leipzig, 1953, pages 708 and 709), which consists of a ferrite rod and a coil winding attached to it. Due to the high permeability of the ferrite material, it is in the coil winding induced emf much larger than that in a stretched wire of the same length EMF induced by the electric field.

The object of the invention is, in a receiving antenna of the type mentioned to increase the bandwidth significantly and at the same time to reduce the overall length considerably and a slim inconspicuous design without additional side bracket. to reach.

According to the invention, the object is achieved by the characterizing features of claim 1 solved.

Advantageous refinements and developments of the receiving antenna according to claim 1 result from the subclaims.

The invention is explained in more detail below with reference to the drawings. It shows: FIG. 1 a schematic view of an exemplary embodiment of one according to the invention Receiving antenna, and FIG. 2 shows a cross section through a ferrite cylinder of the receiving antenna according to Fig. 1.

The antenna denoted by 1 in FIG. 1 for receiving ultra-short waves is used in particular to receive larger microphone signals that are transmitted wirelessly TV studios, halls or theaters whose carrier frequency is that of the Germans The range assigned to the Bundespost is from 32 MHz to 38 MHz (corresponding to 7.9 to 9.37 Meters). When using multiple wireless microphones with The receiving antenna 1 must have a bandwidth corresponding to different transmission frequencies of 6 MHz for the entire range from 32 to 38 MHz, thus a qualitative high quality transmission on radio channels is guaranteed. In addition to the relative large bandwidth of the receiving antenna 1 may be its total length. in special applications e.g. in small studios do not exceed 2.20 m. Has an X / 2 resonance antenna but in a frequency range of 32-38 MHz over a length of 4.3 m Known A / 2 resonance antennas cannot be used for this reason.

There are also known active antennas for wireless transmission of microphone signals cannot be taken into account, as the intermodulation products that arise there prevent the transmission of clear and interference-free useful signals.

The antenna 1 according to FIG. 1 comprises - viewed from bottom to top - one lower pipe section 10, a first ferrite cylinder 30a, a second ferrite cylinder 40a, a third ferrite cylinder 40b, a fourth ferrite cylinder 30b and one Upper pipe section 20. Place the first and fourth ferrite cylinders 30a, 30b first, for example low-permeability ferrite sections, while the second and third ferrite cylinder 40a, 40b, second, for example highly permeable ferrite sections represent.

The components 10, 30a, 40a, 40b, 30b, 20 are mutually electrical isolated.

Through the interior of the lower tube section 10 and the ferrite cylinder A coaxial connection cable 90 is passed through 30a, 40a and is even closer in one connected to a transmitter 100 to be explained. The ferrite cylinders 30a, 30b, 40a, 40b preferably consist, according to FIG. 2, of a bundle of several ferrite rods 2, which are grouped around a central insulating tube 3 and cast in synthetic resin.

On each of the ferrite cylinders 40a, 40b is a coil winding 51 or 61 applied, which together with an adjustable capacitor 52 or 62 a LC resonance circuit 50 or 60 forms. The center frequencies f1 and f2 of the LC resonance circuits 50, 60 are selected differently in the manner described below.

The coil windings 51 and 61- are each fitted with one thereon Decoupling coil 70 or 80 inductively coupled. The two decoupling coils 70, 80 are electrically connected in series and connected to the transformer 100. Parallel A parallel LC circuit 110 is arranged in relation to the two decoupling coils 70, 80.

Coils 31a and 31b are attached to each of the ferrite cylinders 30a, 30b, which are dimensioned in such a way that an optimum is related to the entire antenna effective length and thus an induced voltage. The coils 31a, 31b become hence hereinafter referred to as extension coils. The extension spool .31a is at one end to the lower pipe section 10 and at its other end galvanically connected to the coil winding 50.

The extension coil 3lb is similarly at its one end to the upper pipe section 20 and at its other end to the upper LC resonance circuit 60 connected.

The transformer 100 comprises, for example, four windings 111, 112, 113 and 114, which consist of symmetrical flat ribbon cables with a characteristic impedance of Z = 120 Ohms exist. The windings of the transformer 100 are parallel and on the input side connected in series on the output side. This results in a transmission ratio of 1: 4, with the characteristic impedance Z of the wound line at the parallel switched side with Z / 2 symmetrical and at the other end connected in series appears symmetrical as 2 Z. The side of the transformer 100 connected in parallel corresponds to the connection value of the wave impedance of the coaxial supply cable.

The antenna principle is based on the following consideration: - A reduced Size compared to an A / 2 resonance antenna to the same extent as larger ones Metal pipe sections of common dipoles through small, con- centered Ferrite coil sections can be replaced.

- The bandwidth is determined independently of the antenna length in relation to the wavelength, namely by non-coupling, damped oscillating circuits, the curve of which is essentially determined by ferrites.

Forms in the area of their ferrite sections (coils 30a, 30b, 40a and 40b) the antenna has the greatest antenna current concentration compared to its metal pipe sections. This results in a much greater effective length than the equivalent length of a metal tube Length dimension. The antenna bandwidth is determined by the ferrite inductors of the LC resonance circuits 50 and 60, respectively, whose center frequencies f1 and 2 in the Close to the upper or lower limit frequency of the transmission range. In order to the resonance circles simultaneously serve a second purpose, namely as far as possible Induction of a large amount of HF voltage can lead to their dipole-like structure for a relatively long time Ferrite rods are used. This allows the individual turns of the coils with greater distance to wrap (low coupling) and thus more tension-creating To get turns. The choice of a ferrite material with a certain initial permeability ßA for use as a circular inductance is not the only decisive factor in achieving it a desired circular transmission curve, but it is also of the ferrite shape, the structure of the windings and their arrangement relative to the ferrite core. the then taking effect permeability is the effective permeability under consideration of these factors and influences results in transmission curves of the circles 50, 60 with their center frequencies f11, f2, which mutually overlap and lead to a resulting transmission curve with the desired bandwidth. To increase the sensitivity of the ferrite circular dipole according to the formula Uind = heff E (Uind = induced voltage, heff = effective length, Eo = field strength) are inductive to him Receiving structure in the form of ferrite cylinder coils 30a and 31a and 30b and 31b symmetrically arranged and galvanically coupled. The l / d ratio (l / d = length / diameter ratio) the bundling of ferrite rods and the number of turns can be maximized here optimize heff. This inductive receiving structure can act as a kind of antenna extension coil be understood. This means switching on a coil in the current range an antenna if it is to be tuned to a longer wave than yours Eigenwelle corresponds to. The use of ferrites has reached its limit there, where their alternating field losses exceed the copper losses of the coil winding. Therefore is any increase in length and diameter, as in this case the ferrite cylinder, excluded. Although the antenna ferrite section of the combined Metal tube ferrite antenna is a complete receiving antenna in itself, its sensitivity is still too low compared to an A / 2 resonance dipole. For this reason, the metal pipe sections are important components of the antenna.

When determining their length in favor of increasing the sensitivity A longer end tube and a top tube are found to be most effective. The explanation for this behavior is that it is the length of the pipe section 10 of approx. 0.14 X with its 31 51 extension spool / and the lower circle spool reduced to a total electrical length of S / 4 resonance length.

The upper pipe section 20, which is preferably a somewhat larger Diameter than the lower pipe section 10 has, also carries substantially contributes to the fact that the antenna has such an impedance to match with to be able to carry out a 1: 4 transtrmation. The combined ferrite metal tube antenna only achieves a height of 2 m. It is at least as powerful as an expensive one constructed A / 2 resonance antenna, the height of which in this frequency range is 4.3 m amounts to. This means that it is below the antenna height of an A / 2 resonance antenna more than 50%. Due to its slim, inconspicuous design, it can be, as with Broadcasts in studios desired, easily integrated into the backdrop.

The antenna according to the invention is, however, based on that given above Use not restricted. The main area of application is the meter wave range in those cases where a smaller size with a narrow or larger bandwidth is desirable.

When used as a horizontally polarized antenna, it is symmetrical, with metal pipe sections of equal length and vertical cable routing from run from the center.

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Claims (6)

PATENT CLAIMS - (U receiving antenna for ultrashort waves, in particular for electromagnetic waves in the range from 32 MHz to 38 MHz, with - two separated pipe sections attached one above the other, and - a coaxial connection cable, which is guided within the lower pipe section, g e k e n n n z e i c h n e t d u r c h the following additional features: a) Between the two pipe sections (10, 20) made of metal are first ferrite sections (30a, 30b) and second Ferrite sections (40a, 40b) each with different length / diameter ratios and substantially less permeability symmetrical to each other but separate attached one above the other; b) the second ferrite sections (40a, 40b) are each from the coil winding (51 or 61) of an associated LC resonance circuit (50 or 60), the LC resonance circles (50, 60) having different center frequencies (f1 or f2) and are essentially not coupled to one another, and c) the LC resonance circuits (50, 60) are each connected to an associated decoupling coil (70 or 80) with a transformer connected to the coaxial connection cable (90) (100) connected, which the impedances of the decoupling coils (70, 80) on the characteristic impedance of the connecting cable (90) is transformed and the balancing is carried out. 2. Antenna according to claim 1, characterized in that the first and the second ferrite sections (30a, 30b; 40a, 40b) each have two ferrite cylinders (30a and 30b or 40a and 40b) and that each ferrite cylinder of the first Ferrite sections (30a, 30b) between one of the tube sections (10 or 20) and one the ferrite cylinder (40a or 40b) of the second ferrite sections (40a, 40b) is. 3. Antenna according to claim 2, characterized in that each ferrite cylinder (30a, 30b) of the first ferrite sections is surrounded by a coil (31a or 31b), which on the one hand with the adjacent pipe section (10 or 20) and on the other hand with the adjacent ferrite cylinder (40a or 40b) of the second ferrite sections surrounding coil winding (51 or 52) of one of the two LC resonance circuits (50 or 60) is connected. 4. Antenna according to one of claims 1 to 3, characterized in that that each decoupling coil (70, 80) on the coil winding (51 or 61) of the associated LC resonance circuit (50 or 60) is attached. 5. Antenna according to one of claims 1 to 4, characterized in that that the decoupling coils (70, 80) are electrically connected in series and that in parallel to two decoupling coils (70, 80) a parallel LC circuit (110) to compensate for the inductive reactive component of the antenna impedance is arranged. 6. Antenna according to one of claims 1 to 5, characterized in that that each ferrite cylinder (30a, 30b, 40a, 40b) to increase the force flux density consists of a bundle of cylindrical ferrite rods (2) around a central insulating tube (3) are grouped.