DE2703258C2 - Taps based on the directional coupler principle with different tubular core transformers - Google Patents

Description

45

Transmission devices according to the preamble of claim 1 are known from practice and are used in particular as single or in a chain connection as multiple branches in communal antenna systems used.

Such devices should mainly have the following technical characteristics within their entire operating frequency range Meet requirements:

1. High coupling attenuation (good decoupling) between the first output and the second output (Branch)

2. Small attenuation between input and first output (trunk through loss)

3. High return loss (good match) at all connections.

The known transmission devices of the type mentioned each have two identical tubular core transmitters and thus meet the requirement

65 1 by strictly adhering to the basic condition for the directional coupler principle, namely the same transmission ratio of the two transformers. On the other hand, they only insufficiently meet the other two important requirements for many applications. This is especially true for the standard transmission loss at higher frequencies and for the return loss at low frequencies.

This serious disadvantage results from the fact that for the two requirements mentioned Core dimensions and the number of primary turns (with "primary" are the transformer windings with the small number of turns) of the first transformer would have to meet contrary conditions: for small trunk throughput loss, they should be dimensioned as small as possible for the highest possible return loss at the second output (branch), however, large at low frequencies, so that the inductance of the Secondary winding is as large as possible. Both cannot be achieved at the same time, because the transmission ratio the transformer by the desired value of the attenuation of the second output (branch attenuation) is fixed. Since the transformers are identical, the inductive resistance of the secondary winding is also the second Transformer relatively small, so that the return loss of input and output also are too low.

In the known transmission devices of the type mentioned, therefore, when dimensioning the two identical transformer is a technically unsatisfactory compromise between low transmission loss and the transmission quality at low frequencies. This disadvantage can be particularly common in Daisy chain connection of several such transmission devices, with which the trunk passage attenuation add up and the resulting resistance of the secondary transmission windings is reduced, lead to the fact that a meaningful practical use is no longer possible.

To improve the return attenuation at low frequencies, it is known from DE-OS 23 43 403 to connect a ferromagnetic component 29,30 which increases the inductance of the secondary windings between the base and ground in a differential transformer with a double hole core. This solution has not only the disadvantage that an additional component is required, but also that by Richtkopplerwirkung affecting phase and amplitude errors coupling loss ^zw: rule output and branch is reduced. To avoid this disadvantage, a further inductance 32, 33, 34 is required. This known transmission device thus works with a very complex circuit which, in addition, in no way improves the trunk transmission loss.

This also applies to a known transmission device according to DE-AS 24 48 737, in which the secondary windings have different numbers of turns and which, moreover, also relate to one Transmitter with double hole core and not to two separate tubular core transformers as the subject of the application relates. In addition, the approximately same transmission ratio required in claim 2 could obviously be achieved of the two transformers cannot be implemented (see column 3, penultimate paragraph: 1: 7 for first, 1: 9 with the second transformer), so that the directional effect because of the amplitude errors that occur decreased and therefore not the optimal one

Decoupling is achieved (coupling steam only 3OdB compared to> 40dB in the exemplary embodiment of the subject of the application according to FIG. 3).

The invention has for its object to conceptualize a transmission device according to the Obei To create claim 1, while avoiding all the disadvantages mentioned on the simplest and possible inexpensive way a low trunk transmission loss for the entire transmission frequency range and high return loss is guaranteed for all connections.

According to the invention, this object is achieved by what is stated in the characterizing part of this claim Measures resolved.

The small dimensions of the tubular core of the first transformer result in low magnetic core losses and because of the short windings, there is also little scattering loss. By choosing a core material With a low relative permeability, the core losses can be reduced even further, so that overall a minimum starom transmission loss is achieved. In contrast, the larger tubular core of the second transformer reduces the inductance of its secondary winding large enough to achieve a high return loss at the input and output even at low frequencies guarantee.

In the practical dimensioning of the number of turns z. B. proceed as follows:

The primary winding of the first transformer is simply a straight conductor passed through the pipe core bore (corresponds to approximately ² Λ turns electrically), because this is a symmetrical arrangement of the secondary winding and thus an optimal application of the measures according to claims 3 and 4, as well as the first feature of claim 2 and with a view to low trunk throughput loss, the aim is to achieve the lowest possible number of primary turns in any case.

It is advantageous to use the wire because of the low attenuation. silver. When measuring his In terms of diameter, a compromise has to be made: On the one hand, the wire may be used because of the required low damping should not be too thin, and on the other hand not too thick, because otherwise the secondary winding existing winding capacity increases and the upper limit frequency is adversely affected.

With the number of primary turns and the transmission ratio determined by the desired branch attenuation is *, also determines the number of secondary turns of the first transformer. Now the dimensions and / or the material of the tube core selected so that the connection resistance of the second Output (branch) parallel inductive resistance of the secondary winding of the first transformer is just large enough to ensure the required return loss value at the branch.

Such a dimensioning of the first transformer with the smallest possible values of the number of primary turns and the dimensions and / or the relative permeability of the tube core results in very little core and Scattering losses, so that the trunk transmission loss is small and, above all, only towards high frequencies increases extremely slightly.

Practice shows that it is not necessary to compare the number of turns of the second transformer to change those of the first; it is only the dimensions and / or the material of the core so too choose that the inductance of a secondary winding and thus their input and output impedance of the Tap inductive resistance connected in parallel is large enough to achieve the desired value of the corresponding return loss even at the lowest frequencies of the transmission frequency range to reach. The resulting higher inductance of the primary winding makes itself felt in the The second transformer is nowhere near as annoying as the first and does not cause any significant impairment of the trunk throughput attenuation. Of course, other numbers of turns can also be used than for the first transformer, but it should be noted that the desired inductance can be better achieved by changing the core accordingly than by increasing the number of turns.

Due to the inventive measures according to claim 1 are therefore without the slightest additional effort of material ^r ode elegantly satisfied the above-mentioned technical requirements in the manufacture and at maximum Koppeidämpfung between the outputs.

In one embodiment of the transmission device according to the invention according to claim 2 is through the The first-mentioned characteristic feature is the leakage inductance of the secondary winding that loads the trunk line significantly reduced compared to a winding with contiguous turns and thus carries contributes to a further reduction in the trunk throughput loss.

jo By the two characteristic features this Claim is a favorable compromise between an increasing or decreasing frequency with increasing frequency increasing decoupling attenuation with closely or widely spaced turns a constant Educate course over the entire transmission frequency range.

In a transmission device according to claim 3, the first transmitter advantageously has the Lowest possible independent of manufacturing deviations Winding capacity between the primary and secondary winding, and thus also in volume production constant coupling attenuation between the first and second output, even with the highest Frequencies of the range to be transmitted. Production is particularly simple and inexpensive such a transformer by an embodiment according to claim 4.

The figures show an embodiment of the transmission device according to the invention as a double branch. Where F i g. 1 shows a basic circuit diagram and FIG. 2 shows the perspective view of the two Tubular core transmitter each of the in F i g. 1 single branch marked by a dashed frame, the first transmitter in FIG. 2a and the second transmitter in FIG. 2b is shown. F i g. 3 shows the frequency responses of the following attenuation of a single tap: trunk throughput loss between Input and output, coupling attenuation between output and branch, branch attenuation between Inlet and branch, as well as the return loss for all three connections. Here are the curves a branch with identical transformers used in a known manner (dashed) to those of one Splitter with a structure according to the invention (durchgeb5 draws: :) compared, with both branches for constant decoupling attenuation are designed.

According to Fig. 1, the double tap has an input 1, an output 2, and two equal-

te branch connections 3 and 4. During the main part of the radio frequency energy over the trunk line 5 is passed from input 1 to output 2, only a relatively small part reaches the Ports 3 and 4.

It is determined by the selected decoupling attenuation, which is achieved by a corresponding transmission ratio (ratio of the number of turns of the primary to the secondary winding of the two transformers Ü 1 and Ö2). These are interconnected using directional coupler technology so that the highest possible decoupling between output 2 and the respective branch 3, 4 is guaranteed. The circuit is structured as follows: The primary windings of the oil transformer are connected to the main line 5, the secondary winding is connected to ground on one side via a line 6 and leads on the other side via the line 7 to the respective branch connection 3, 4.

The primary winding 5 'of the second transformer L / 2 is each connected once to the line 7 and on the other hand via a parallel circuit from an ohmic Resistor 8 and a capacitor 9 to ground; their secondary windings are each over Lines 10 and 11 between the input 1 or trunk line 5 and ground.

The two transformer oil or Ü2 of each individual branch wound on separate tube cores 12 and 13 have the same transmission ratios, so that the antiphase voltages at the branch connections, which are decisive for the directional coupler principle, are of the same magnitude and thus extinguish. The ohmic resistor 8 is to be understood as the terminating resistor of an imaginary fourth port and thus as a necessary component of the directional coupler. It is therefore dimensioned so that, on the one hand, the decoupling is as great as possible and, on the other hand, the return loss at the branch reaches the required value, especially at low frequencies (in the present embodiment approx. 75 ohms). The capacitor9 compensates for unavoidable leakage inductances and capacitances and thus improves the decoupling at high frequencies.

The tap attenuation in this exemplary embodiment is 13 dB, and the transmission ratio accordingly about 1: 4.5.

Since the primary windings only of a straight, guided by the respective core bore 14 wire conductors 5, 5 '(electric about _{^2/3 of} turns) which have the respective secondary windings

have three turns 15, 16, 17 or 15 ', 16', 17 '.

In the known taps of this type, the tube cores 12, 13 of the two transmitters oil, Ö2 in Same size and texture.

This gives you the single tap in the frequency range from 40-860MHz as shown in FIG. 3 curves 18 to 23 shown in dashed lines in this order for the trunk throughput loss, the branch loss, the coupling loss between output 2 and Branches 3, 4 and the return damping for connections 1, 2 and 3 or 4.

If, however, according to the invention, the tubular core 12 is selected only about half as long as the tubular core 13 with otherwise the same dimensions and the same material, the three turns 15, 16, 17 of the secondary winding of the transformer U 1 are distributed evenly around the circumference (Fig. 2a ) and arranges those 15 ', 16', 17 'of the secondary winding of the transformer Ö2 relatively close together (Fig. 2b), it is in a simple manner without any additional expenditure a decisive improvement in the trunk throughput attenuation, the coupling attenuation between output 2 and branches 3 , 4, and the return loss at the inlet and outlet according to the solid curves 24, 26, 27 and 28 in FIG. 3 reached. The requirement for constant decoupling attenuation is fulfilled according to curve 25, the return attenuation at branch 3, 4 is still above the values according to the recommendation of the professional association receiving agent. in the ZVEl.

An insulating tube 30, which envelops the straight conductor 5 of the oil transformer, is selected in terms of its strength so that that he has a central guide in the core bore 14 and the symmetrical arrangement of the secondary winding according to claim 2 allows.

It has already been stated that those achieved by applying the measures according to the invention Advantages with regard to the trunk throughput loss and the return loss of input and output Compared to the known solutions, the more individual branches in the chain are, the more important it is are interconnected with a multiple tap. Nevertheless, this backflow loss is thereby Naturally small in absolute terms To avoid this disadvantage as far as possible, the Invention useful in such devices, the ratio of the tube core dimensions of the transformer Ö2 to transformer oil to increase gradually with increasing number of individual branches.

For this purpose 2 sheets of drawings

Claims (5)

Patent claims: 1. Device with one input and two outputs for broadband, direction-dependent transmission of high-frequency signals, consisting of two separate tubular core transmitters which are constructed and connected in such a way that a first winding located between the input and the first output and one between the second output and ground second winding on the first tube core, as well as a third winding lying between the input and ground and a fourth winding provided between the second output and a resistor connected to ground are wound on the second tube core, characterized in that the volume and / or the relative Permeability of the tube core (! 2) of the first transducer (Cl 1) is less than that of the tube core (13) of the second transformer (Ü2). 2. Device according to claim 1, characterized in that the turns of the secondary winding of the first transformer (Ü \) are evenly distributed on the circumference of the tubular core (12) and those of the secondary winding of the second transformer (Ü2) are relatively close to one another. 3. Device according to claim 1 or 2, characterized in that within the core bore (14) of the first transformer (Cl \) the primary winding has a constant distance from the secondary winding. 4. Device according to claim 3, characterized in that between the primary and secondary winding Insulating material (30) with the smallest possible loss angle and a small relative dielectric constant is arranged. 5. Chain connection of devices according to one of claims 1 to 4, characterized in that the ratio of the Ro'nrkernab measurements of the second transformer (Ü2) to the first transformer (Cl \) is increased in steps with an increasing number of devices.