DK143220B - DISTRIBUTION OR RANGE LINK TO HIGH FREQUENCY SIGNALS - Google Patents

Description

ι \ ΐ | (11) PUBLICATION 143220 DENMARK '') Int. c.! H 03 H 7/48 Section (21) Application No. 1 539/74 (22) Filed on the 20th tTlSP. 19 74 (24) Race stage Mar 20 1 974 (44) The application submitted and the presentation document published on 20 Jul · 1 9 -1

DIRECTORATE OF

PATENT AND TRADEMARKET SYSTEM (30) Priori, a ***** from

Mar 21 1973 ^ 2314039, DE

(41) Aim. avail. Sep 22 1974 <71> ROBERT BOSCH ELEKTRONIK GMBH, D-1000 Berlin 33j Forckenbeckstras = see 9-1 3j DE.

(72) Inventor: Karl Dillnberger, D-1000 Berlin 31, Seesener Strasse 33, DE.

(74) Plenipotentiary in the proceedings:

International Patent Bureau .__ (54) Distribution or branching frequency for high frequency signals.

BACKGROUND OF THE INVENTION 1. Field of the Invention This invention relates to a distribution or branching line for high frequency signals, particularly to television and radio signals in common antenna systems, with a directional broadband transmission means with inductively coupled conductors and / or windings, and with four connections, preferably in fork coupling, the first connection of which is connected to a line. the high frequency signals, the second connection of which is connected to a conduit which transmits the high frequency signals, the third connection of which is connected to a conduit which conveys a certain energy proportion of the high frequency signals, and the fourth connection of which is grounded.

Depending on whether a high-frequency conduit supplying high-frequency signals has to be switched off the same or different parts of the high-frequency energy, you are talking about distribution or branching lines. one connected to an incoming main line, one to the outgoing 2

1Λ 3 2 2 G

a main line output, over which the vast majority of arriving high-frequency energy is passed on to other consumers, and a branch line or connector coupled to the main line over which a certain portion of the arriving high-frequency energy is branched.

From German Patent Specification 1,276,146 there is known a branching coupling having an ohmic switching resistance and an adaptable transferring means, the foot point of which is connected to a frame over a capacitor. The capacitor's reactance assumes at the frequencies of the long, medium and short wave ranges such that the transfer means no longer have any effect and essentially only the switch-off resistance is effective. Transmission means and capacitor together form a series resonant circuit which leads to a point lying between the short-wave region and the television area I in the attenuation characteristic of the branching coupling.

The known branch coupling has no directional dependence. Therefore, it cannot meet the current requirements for branching in common antenna systems in terms of good attenuation properties in a wide frequency range. In particular, the tripping resistance acting in both directions turns out to be disturbing.

The object of the invention is to improve a distribution or branching link with a directional broadband transmitter in such a way that, in addition to television signals, it also transmits signals within the long, medium and short wave range with a sufficient level to hold the necessary call. as low as possible.

According to the invention, this task is solved at a distribution or branching line of the type mentioned in the first, by means of a maximum raising of the level of the high frequency signals within the long, medium and short wave radio to be transmitted, between the fourth connection and frame is a capacitor which has a high impedance for the frequencies in said radio range and that at least one self-induction is connected between the third and / or the fourth connection and frame.

A distribution or branching link with the aforementioned features raises the level of the signals within the long, medium and shortwave radio range to such an extent that it has, for example, the same value as the level of the television signals.

Details of the invention will be explained with reference to various embodiments shown in the drawing, FIG. 1 shows a principle diagram of a known branching link with a directional broadband transmission means in fork coupling; FIG. 2 is a block diagram of a transfer means, the base of which over a capacitor is connected to the frame; FIG. 3 is a diagram of a directional broadband transmission means, the foot of which is connected to a frame via a parallel coupling of a capacitor and a self-induction; FIG. 4 is a block diagram of a directional broadband transmission means, the base of which is grounded over a capacitor and whose third connection is grounded over a self-induction; FIG. 5 is a block diagram of a directional broadband transmission means, the foot of which is grounded over a parallel coupling of a capacitor and self-induction, and whose third connection is grounded over a self-induction; FIG. 6 shows the decoupling attenuation of a branching joint as shown in FIG. 5 depending on the frequency.

In the principle diagram of FIG. 1 is denoted by 1 a directional broadband transmission means in fork coupling, such as e.g. applies as a branch in joint aerial systems. Such a branch line has a first connection (input) 3 connected to a high frequency line 2 (main line) supplying the radio and television signals, and a second connection 5 (output) connected to an output high frequency line 4, over which the largest part of the arriving high frequency energy is passed on, a third connection 7 (plug) connected to a plug line 6, over which a certain part of the arriving high frequency energy is switched off, and a fourth connection 8 (frame), which is directly connected to the frame. The 1 punctured, indicated resistors 9, 10, 11 symbolize the wave resistances of the connected high frequency wires 2, 4 and 6.

From the first connection 3, a first conduit 12 leads to the second connection 5 and a first winding 13 to the fourth connection 8. A second conduit 14 connects the third connection 7 to the fourth connection 8, between the latter connection and the second connection 8. wiring piece 14 is a terminating resistor 15. Between the third and fourth terminals 7 and 8 there is also a second winding 16.

The wires 12 and 14 and the windings 13 and 16 are magnetically coupled to each other, namely the first wiring 12 with the second winding 16 and the second wiring 14 with the first winding 13, cf. they dotted lines between the wires and the windings.

In order for a signal voltage lying in the long, medium and short wave region at the input (E) of the directional broadband transmitting means 1, (Fig. 1) to occur at a sufficient level at the output (A) and the branch (S), ensure that the said signal voltage is not diverted over the first winding 13 to the frame, which would result in a curve loss for the switch-off damping D, ie. the attenuation between the first connector 3 (input) and the third connector 7 (connector), as indicated by the dashed line A

143220 4 in FIG. 6. At this curve, the long- and medium-wave (L, M) signals would be attenuated sharply and parts of the short-wave region (K) would be attenuated somewhat.

A far more favorable curve is obtained when, as shown in FIG. 2, a capacitor 17 interconnects between the connector 8 for the sake of clarity, indicated by a block diagram symbol 100, directional broadband transmission means and frame. Thereby, the FIG. 6 in a dashed line B, the curve shown. In this case, the capacitance value of capacitor 17 determines the location of a resonant site R, such as e.g. can be at approx. 2MHz. The curve curve B clearly shows that the level of the signals in the long and medium wave range can be raised by means of a capacitor with a certain capacity value, but on the other hand the attenuation course is still very irregular.

A somewhat offset curve is obtained when, according to a first embodiment of the invention, the capacitor 17 is connected in parallel with a self-induction 18, cf. FIG. 3, so that in connection with the self-induction of the directional broadband transmission means 100, a resonant network is formed whose resonance frequency is within the long, medium and short wave radio range. An ohmic resistor 19 with the self-induction 18 in series serves to obtain a self-induction of particular goodness, on which the linearity of the curve course depends.

A practically sufficient linearization of the curve is possible when, according to another embodiment of the invention, cf. FIG. 4, between the fourth connection 8 and the frame is a capacitor 20 and between the third connection 7 and the frame there is a series connection of a self-induction 21 and an ohmic resistor 22. The capacitor 20, the self-induction 21 and the ohmic resistor 22, for example, have the same in FIG. 4 values.

However, a largely linear curve is obtained only when according to a third embodiment of the invention between the fourth connection 8 of the directional broadband transmission means 100 and frame a parallel connection of a capacitor 23 and a serial connection of a self-induction 24 and an ohmic resistor 25 is found. and between the third connection 7 and the frame a series connection of a self-induction 26 and an ohmic resistor 27.

A branch line similar to the embodiment of FIG. 5 has a curve C as shown in FIG. 6, where the capacitance value of the capacitor 23 * influences the location of the resonant site R, the self-inductors 24 and 26 affect the cut-out attenuation D, and the resistors 25 and 27 influence the increase of the curve in the long and medium wave range (L, M), cf. the dotted line D in FIG. 6th

For the construction of a branch line according to FIG. 3, 4 and 5 it has been found

Claims (2)

It is convenient to wrap the self-inducers 18, 21, 24 and 26 of such a wire that the self-inducers have an ohmic resistance value corresponding to the resistance value of the ohmic resistors 19,22, 25 and 27. Thereby the aforementioned resistors may lapse. Furthermore, it is advantageous as a directional broadband transmission means to use a fork coupling transmitter having a ferromagnetic core with two axis parallel holes. This core carries four windings, the first and third windings corresponding to the wires 12 and 14 of FIG. 1, and the second and fourth windings correspond to the other two windings 13 and 16. The windings are wound on the double holes as follows: From a first connection on the transfer means, the first winding is wound through the first hole in the double hole core and connected to the second connection. The third winding is wound through the second hole in the opposite direction. It connects the third connection to the frame over a terminating resistor. Through the second hole in the double hollow core is further wound the second winding which connects the first connection to the frame, and through the first hole is wound the fourth winding which lies between the third connection and the frame. Thereby, the first and third coils must have a smaller winding number than the second and fourth coils. The use of such a broadband transmission means simultaneously results in a relatively high cut-off attenuation between the third and the second connection, which is necessary for interference-free signal transmission. 1. Distribution or branching line for high frequency signals, especially for television and radio signals in common antenna systems, with a directional broadband transmission means with inductively coupled conductors and / or windings and with four connections, preferably in fork coupling, the first connection of which is connected to a high frequency supply signal , the second connection being connected to a line which transmits the high frequency signals, the third connection being connected to a line passing on a certain energy share of the high frequency signals, and the fourth connection being grounded, characterized in that for the purpose of a uniform, as far as possible raising the level of the high frequency signals in the long, medium and short wave range to be transmitted between the fourth connection (8) and frame is connected a capacitor (17, 20) which has a high impedance for the frequencies in said radio range , and that between the third and / or the fourth connection g (7, 8) and frame are connected to at least one self-induction (18, 21, 24, 26).