DE2257960A1 - DIRECTIONAL BROADBAND TRANSMITTER - Google Patents

Description

Directional Broadband Transmitter The invention relates to on a directional broadband transmitter with two side by side ferromagnetic perforated cores, which together form a hybrid circuit with windings are provided, especially for branches or distributors in community antenna systems.

Depending on whether high-frequency energy is brought in via a high-frequency line is to be transmitted to outgoing lines in equal or unequal proportions, I speak of distributing or tapping. One used in community antenna systems Branch has, for example, one with an incoming high-frequency line (trunk line) connected output, through which the vast majority of the incoming high frequency energy is forwarded, and a branch (branch) coupled to the trunk line, to which a branch line is connected, over which a certain proportion of the incoming High frequency energy is diverted.

if If to prevent interference As high as possible decoupling attenuation prevails between the output and the branch is to, one often uses transformers from telecommunications technology under the Designation hybrid circuit are known. With a community antenna systems one has Such transformers have so far usually consisted of two spatially separated cylindrical ones Ferrite cores built, each having an axial hole and the required Wear windings. Transformers of this type have a maximum achievable decoupling attenuation in the range of television frequencies (around 40 to 800 MHz) of around 25 to 30 dB.

For the purposes mentioned at the beginning, right-hand couplers are also used, with those in the specified frequency range only slightly higher decoupling attenuations are attainable.

The invention is based on the object of a direction-dependent To develop broadband transducers in hybrid circuit, through better electrical Separation between the primary and secondary electrostatic fields of transmission should result in a higher decoupling damping.

According to the invention, this object is achieved in the case of a direction-dependent broadband transmitter of the type mentioned at the beginning solved by that between the two Perforated cores a shielding wall connected to ground made of a non-magnetic metal is provided that is perpendicular to one extending through both longitudinal axes of the perforated cores Level stands.

Through the shielding wall made of non-magnetic metal between the two Perforated cores will largely separate the electrostatic fields and thus a better decoupling is achieved.

According to an advantageous embodiment of the invention, the contains Shielding wall at least one opening for the passage between the two perforated cores provided winding parts of the windings. This measure enables the shortest possible Cable connection between the two perforated cores.

Further details of the invention are found at one in the drawing illustrated embodiment. In the drawing: Fig. 1 a schematic diagram of a known broadband transmitter in hybrid connection with two perforated cores and FIG. 2 is a perspective view of a broadband transmitter in hybrid circuit.

A A well-known directional Breltband transmitter In the Gabeischaitung has an asymmetrical one according to the basic circuit diagram in FIG Input 1, an unbalanced output 2 and a branch 3. From the input 1 leads a first line piece 4 through a hole 5 of a first ferromagnetic Hole core 6. Between the input 1 and ground there is one through a hole 7 of a second ferromagnetic perforated core 8 guided first winding 9. During a second line piece 10 from the branch 3 (branch) through the hole 7 of the second Hole core 8 stirs through a terminating resistor 11 to ground, connects a second winding 12 wound through the hole 5 of the first perforated core 6 forms the branch 3 with ground. The perforated cores 6; 8 are, for example, cylindrical.

The resistors 13 indicated by dashed lines in FIG symbolizes the wave resistance of the coaxial cables connected to the transformer.

If a Breltband transformer according to the circuit principle in Fig. 1 For example, used as a tap in a community antenna system, so lie input 1 and output 2 between an incoming and outgoing trunk line.

While the main part of a television antenna or one with it in order to connected amplifier device via the incoming trunk line Received energy is passed on to output 2 of the transmitter, arrives lower proportion to a branch line connected to branch 3.

A tap should not only put the incoming high frequency energy in split two different sized parts but he has to do it at the same time ensure that between the off gear 2 and the junction 3 a much higher attenuation (= Directional attenuation9 prevails than between input 1 and branch 3 (= connection attenuation) as well as between input 1 and output 2 (= throughput loss).

To with a directional broadband transmitter in hybrid connection To achieve the highest possible directional attenuation, according to the embodiment in Fig. 2 between two ferromagnetic perforated cores 14, 15 with a hybrid circuit forming windings 16, 17 are provided, a shielding wall 18 made of a non-magnetic Metal provided.

The shielding wall 18 can be made of copper or aluminum, for example exist. For reasons of stability, it has a wall thickness of 0.5 mm and its length should be greater than the length of the perforated cores 14, 15.

In Rest in the embodiment according to FIG both perforated cores 14, 15 on the copper lamination 19 of a printed circuit board 20 made of insulating material. The shielding wall 18 between the two perforated cores 14, 15 has one longitudinal edge two pins 21 which fit into corresponding openings 22 of the circuit board 20 and be interlaced below the circuit board. An electrically conductive connection between the copper lamination 19 of the printed circuit board 20 and that made of copper Shielding wall 18 is provided by an extending over the entire length of the shielding wall Solder seam 23 reached. In the exemplary embodiment, the shielding wall is even rare for both 18 One solder seam 23, 24 each is provided.

Due to the circuit of the transformer (see. Fig. 1) the windings are 16, 17 of the perforated cores 14, 15 (FIG. 2) are connected to one another via winding parts 25, 26. Therefore, the shielding wall 18 contains a small opening 27 for free passage of the winding parts 25, 26.

The ends 28, 29 of the windings 16, 17 to be connected to ground are on opposite sides of the shielding wall 18 with this, for. B. by Soldering connected.

Those ends 30, 31, 32 of the windings 16. 17 which are connected to the input, The output and branch of the transformer correspond stand with compared to the copper lamination 19 insulated terminals, which are shown in the drawing have been omitted as they are well known in connection.

The broadband transmitter contained in the tap according to FIG the shielding wall 18 can also be used in an antenna socket with the same advantage Communal antenna system.

Claims (7)

Claims Directional broadband transmitter with two side by side ferromagnetic perforated cores, which together form a hybrid circuit with windings are provided, in particular for branches or distributors in communal antenna systems, characterized by the fact that between the two perforated cores (14, 15) one with ground connected shielding wall (18) made of a non-magnetic metal provided ipt, the perpendicular to a plane running through both longitudinal axes of the perforated cores (14, 15) stands. 2. Directional broadband transmitter according to claim 1, characterized characterized in that the shielding wall (18) has at least one opening (27) through which it can pass of the winding parts (25, 26) provided between the two perforated cores (14, 15) of the Contains windings (16, 17). 3. Directional broadband transmitter according to claim 1 or 2, characterized in that the winding ends (28, 29) to be connected to ground of the perforated cores (14, 15) on the side of the shielding wall adjacent to the respective perforated core (18) are soldered on. 4. Directional broadband transmitter according to one of the claims 1 to 3, characterized in that on a copper-clad printed circuit board (20) attached perforated cores (14, 15) the shielding wall (18) perpendicular to the copper cladding (19) is attached by the front edge of the shielding wall resting on the lamination (18) is soldered to the lamination (19) over its entire length. 5. Directional broadband transmitter according to one of the claims l to 4, characterized in that the length of the shielding wall (18) is greater than is the length of the perforated cores (14, 15). 6. Directional broadband transmitter according to claim 1 to 5, characterized in that the shielding wall (18) consists of a non-magnetic metal foil of about 0.5 mm thick. 7. Directional broadband transmitter according to claim 6, characterized characterized in that the shielding wall (18) consists of copper. L e r s e i t e