DE2928437A1 - CIRCUIT AND TRANSFORMATION ARRANGEMENT FOR SPLIT OR SUMMARY OF RF POWER - Google Patents

Description

Patent attorneys Dipl.-lng. Curt Wallach

ζ Dipl.-Ing. Günther Koch

Dipl.-Phys. Dr Tino Haibach

Dipl.-Ing. Rainer Feldkamp

D-8000 Munich 2 Kaufingerstraße 8 Telephone (0 89) 24 02 75 Telex 5 29 513 wakai d

Date: IJ> . July 1979

Our reference: 16 684 - K / Ap

Applicant: Spinner GmbH

Electrotechnical factory
Erzgießereistraße 33
8000 Munich 2

Designation: circuit and transformation arrangement for splitting or
Summary of RF power

030063/0615

The invention relates to a circuit arrangement and a broadband power distributor for splitting (or combining) high frequency power with any Divider ratio.

In transmission systems, power splitters are often required that divide an incoming transmitter power into two or more equal parts or have to split unequal power levels. There is a requirement that in the entire frequency range in question the reflection factor remains unchanged and also the division ratio and the phase position of the split Performance remains constant. In particular, it is required that the phase position of the partial services is the same regardless of frequency.

So far, the the following procedures were used:

If the portion of the power to be coupled out is small compared to the continuous power, coupling loops, capacitive coupling arrangements or directional couplers are used. The directional couplers normally cause a phase jump that is independent of frequency, i.e. not by a corresponding one Extension line can be compensated broadband. Capacitive and inductive decoupling (also mixed capacitive / inductive Outcouplings) usually have a not inconsiderable frequency response and prepare at high Frequencies particular difficulties.

The invention is based on the object of a circuit arrangement to create with a power splitter that is broadband and enables a division (and combination) of any power fractions.

03006370615

- ο -

The problem posed is achieved by the features specified in the characterizing part of claim 1.

Accordingly, the invention provides a power divider which is based on pure line transformation, the transformation circuits made broadband almost at will can be. If the power is now to be divided into groups over a broadband, e.g. the first group a / n the Power, the second group b / n of the power, etc. are decoupled up to the last group m / n of the power, so will a transformer is used which transforms the connection characteristic impedance Z to the transmitter to a value Z / n. Of this Point, η-lines are now routed as symmetrically as possible with the characteristic impedance Z, and thus corresponds to Total wave resistance of η-lines connected in parallel to the value Z / n at the end of the first transformer. The denominator η is always the smallest portion of the performance that is required (P / n), i.e. at least one line is required, which is supposed to transfer this smallest partial service (but also several who are supposed to transfer the same smallest partial service) each with the characteristic impedance Z to the branch point. Are larger power units in the same arrangement desired, the individual branch lines are interconnected with the characteristic impedance Z and by means of a Transformer brought to nominal value Z. The output transformers therefore have the transmission ratio

Z ; Z or Z ; Z.
dm

The rest of the performance

030063/0615

is then achieved by using a transformer

Z : Z

turns on.

Two examples should be given to illustrate this:

A transmitting antenna consists of two dipole groups, of which the first dipole group should receive 1/7 of the power while the other dipole group should receive 6/7.

A transformer from

used, on the low-resistance part of which there are seven lines can be continued with the wave impedance Z. One of these Lines is connected directly to the dipole antenna that 1/7 of the power should receive while the other 6 lines combined to be connected to a transformer, the transformed from Z / 6 to Z. The output of this transformer again has the characteristic impedance Z and can be led to the other dipole group.

According to a further example, one consumer in a transmission system requires 1/17 of the power, a second 3/17 and a third the remainder of I3 / I7.

Here, according to the teachings of the invention, a Transformer from Z: Z / 17 must be switched on. I7 lines with the characteristic impedance go from the low-resistance side Z continues, one being sent directly to the consumer with I / I7

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is supplied to the power. Three more lines will be summarized and with a transformer from Z / 3: Z to the consumer who needs 3/17 of the power. The lines remaining in Ij5 are also grouped together and fed via a transformer from Z / 13: Z to the consumer who needs 13/17 of the power.

In order to be able to implement odd or other complicated distribution relationships, it is possible to do the same Arrangement to be switched several times in a row.

Further useful refinements of the circuit arrangement according to the invention emerge from subclaims 2 to 6. Further refinements of the power distributor with the transformation arrangement result from the subclaims 7 to I7.

030063/0615

The following is an embodiment of the invention described using a four-way distributor, the two Has outputs that each deliver 1/14 of the input power, while two other outputs each deliver 6/14 of this power. In the drawing show:

1 shows a longitudinal section of a power distributor with four transformation stages;

Fig. 2 on a larger scale a sectional view of the Part II of FIG. 1;

Fig. 5 on a larger scale a sectional view of the Part III according to FIG

FIG. 4 shows a section along the line IV-IV according to FIG. 1 and FIG. 2;

Fig. 5 is a view in the direction of arrow V according to Figs. 1 and 5,

6 shows a section along the line VI-VI according to FIG. 1 and FIG. 5;

FIG. 7 shows a partial section along line VII according to FIG. 6.

The power distributor shown in the drawing is in Shape of a transformation arrangement in coaxial technology executed. It has an input 10 and four outputs 13, 14, 15. The outputs 12 and 14 each deliver 1/14 of the

03006370615

at 10 occurring power, while at the outputs 13 and 15 each 6/14 of this service can be accepted.

The input 10 has an inner conductor 16 and an outer conductor 18, between which insulating supports 19 are arranged are. The outer conductor 18 is connected to a sleeve extension 22 of a junction housing 24 via an outer conductor tube 20. The inner conductor 16 extends in a section of λ. A into an inner conductor sleeve that is galvanically separated from it 26, and it is centered across from this by means of insulating supports. The inner conductor sleeve 26 is in turn over insulating supports 28 and 29 centered in the outer conductor. Inside that part of the inner conductor sleeve facing the branch housing 24 26, a solid inner conductor section 30 is inserted with a radial annular gap and via a screw 32 at its right end connected according to FIG. An inner conductor pin 34 is guided through a central bore in the cover plate 24, which on the right-hand side according to FIG. 1 in the inner conductor section 30 and on the left-hand side in a solid inner conductor section 36 is screwed in. This inner conductor section is in turn enclosed by an inner conductor sleeve 38, with the left end is connected by a screw 40. In the left section, the inner conductor sleeve 38 encloses Spacer sleeves separate an inner conductor shaft 46, via which the coupling takes place. From the left sleeve process 48 the outer conductor continues in a tube 50, the left end of which passes through a housing part 52 is completed. Insulating supports 54 and 55 are arranged between inner conductor sleeve 38 and outer conductor tube 50.

The branch casing 24 has an annular array about the axis of the inner conductor pin 34 in a symmetrical order at 14 to holes 56 in the inner conductor pins 58

O30063 / 0S15

stand in the left face of the inner conductor sleeve 26 used in a corresponding annular arrangement are. The inner conductor pins are on the side facing the sleeve 26 58 supported by insulating supports 60.

As can be seen in particular from FIGS. 3 and 6, opens into of the uppermost and lowermost bores, which are designated with 56A, a radial bore and above this bore 62 is each a support bearing 64 is placed, which is after the outputs

12 or 14 leading outer conductor tube 66 carries. The inner conductor 68 is supported in each tube 66 by means of insulating supports 69. A direct conductor contact piece 72 is inserted into the radial bores 62 by means of an insulating support 70, which makes contact with the inner conductor pin 58A at the radially inner end and rests on the connection of the inner conductor 66 with the fork arranged on the radially outer side.

The arranged in the remaining bores 56 inner conductor pins 58 are brought out to that of FIG. 1 the left side of the closure plate, as seen from the part section according to FIG. J can be recognized and the pins 58, supported within the bore 56 by a further insulating support 61 are, stand in bores of the front side of the inner conductor sleeve 38 on the right according to FIG. 1. In this way the 6 inner conductor pins are combined on both sides. The inner conductor connection with the inner conductor 74 of the outputs

13 or 15 takes place via radial inner conductor plug pins 76, which are inserted into radial bores 78 of the inner conductor shaft 46 and free through holes 80 of the housing part 52 step through. The inner conductors 82 of the outputs 12 and 14 are with inner conductor contact pieces 84 with the connection of the Inner conductor 68 connected.

030 063/0815

The exemplary embodiment shows a power distributor in which 1/14 of the am Input 10 power supplied is removed, and at outputs 13 and 15 each 6/14. If another Power distribution is required, the number of holes in the cover plate 24 must be changed accordingly and adjusted to the common denominator of the required partial services. Some of the connections are guided radially outward in the plane of the cover plate and part of the inner conductor arrangement after the end section. In any case, the transformation is carried out in the desired manner such that the wave impedance at all outputs is the same as the wave impedance at the input. In the illustrated embodiment is a four-step transformation in the Inner conductor provided. The first stage is formed between the inner conductor 16 and the inner conductor sleeve 26, in which the inner conductor 16 protrudes without galvanic connection in a length of ^ / 4. The second transformation stage is from the inner conductor jump 86 of the inner conductor sleeve 26 is formed, and a further transformation stage between parts 26 and J5O, during the last stage is formed by the jump in diameter 88.

Above, the invention was in connection with a Transformation arrangement described by the one Service was divided into a plurality of partial services. However, the same arrangement can also be used use to combine several small services to form a total service ■ by adding outputs and inputs of the described Embodiment are interchanged.

As can be seen from the drawing, the individual

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Transformation sections of the power distributor like this built into each other so that the individual transformation sections can be dismantled and individually with suitable adapters can be measured.

If more complicated distribution relationships than in the example specified, are required, several transformation arrangements according to FIG. 1 in a corresponding Training can be switched one after the other, again in the same way a summary is possible, when the direction of energy is reversed.

The junction box 24, which coaxial lines with the characteristic impedance Z is formed relatively short in the illustrated embodiment. It can also be carried out longer and then at the same time a transformation stage form. The junction housing can then, for example, be designed as a cable, angle piece or the like In particular, the available spatial conditions can be taken into account.

0300S3 / 0S1S

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Claims (17)

Pate nt ans ρ r ü c h e: 1. Circuit arrangement for phase-locked, frequency-independent Division (or aggregation) of RF power, characterized, that a single or multi-stage transformation from (Z) to one corresponding to the largest division ratio (n) reduced characteristic impedance value (Z) is carried out so that at the output the power component (s) that correspond to this greatest division ratio, directly without further transformation with the Characteristic impedance (Z) can be switched on, and that by connecting all of them in parallel with the same Characteristic impedance (Z) to the low-resistance output of the first transformer transformed back to the input wave resistance (Z) by a corresponding transformation ratio will. 2. Circuit arrangement according to claim 1, characterized, that the transformation arrangement is carried out in a coaxial design, and that the division symmetrically into the individual partial powers on the low-resistance side of the input transformer with the corresponding number (n) of coaxial lines of the wave resistance (Z) takes place. 0300B3 / 0615 ORIGINAL. INSPECTED 3. Circuit arrangement according to claim 2, characterized in that the summary of the partial services also takes place symmetrically. 4. Circuit arrangement according to one of claims 1 to 3 » characterized in that the coaxial transformation elements are multi-stage are executed. 5. Circuit arrangement according to claims 1 to 4, characterized in that that the coupling takes place via an open coaxial line (16, 26). 6. Circuit arrangement according to one of claims 1 to 5, characterized in that that several transformation circuits are built in series. 7. Coaxial power distributor for a circuit arrangement according to one of claims 1 to 6, characterized in that at the end of a coaxial transformation section into an inner conductor sleeve (26) on the face side corresponding to the number of the greatest division ratio Number of inner conductor pins (58) are arranged in a ring-shaped arrangement symmetrically around the axis, which are individually led directly to the outputs (12, 14), and which are combined via transformation stages to the outputs (13 * 15). 030083/0815 8. Power distributor according to claim 7, characterized in that the inner conductor pins (58) are in bores a junction housing (24) protrude, which forms the outer conductor and over insulating supports (60) are supported that these coaxial lines formed in the housing (24) the characteristic impedance (Z) have, and that the housing (24) with its sleeve extensions (22, 48) on both sides with the Outer conductors (20 or 50), which the transformation stages included, connected and on the inner conductor (50,34,35) sits over a λ / 4 section are arranged in inner conductor sleeves (26). 9. Power distributor according to claim 8, characterized in that that the outgoing from the low-resistance distribution point Lines are axially parallel. 10. Power distributor according to claim 8, characterized in that that the outgoing lines from the low-resistance distribution point are guided radially. 11. Power distributor according to claims 8 and 9, characterized in that that the inner conductor pins (58) through holes (56) of the branch housing (24) are passed and coaxial line sections with the characteristic impedance (Z) form, and that the inner conductor pins (58) in the end holes of an inner conductor sleeve (38) the subsequent transformation stage are. 030063/0616 12. Power distributor according to claim 1, characterized in that that the radial combination of outgoing or incoming coaxial lines at the corresponding connection point of the transformer takes place in that corresponding radial bores (78) are provided, which through to the outside resilient inner conductor plug pins (76) are contacted. 13. Power distributor according to claims 8 and 10, characterized in that the radial inner conductor sections (72) over Fork contacts contacted with the inner conductor plug pins (58A) within the bore (56A) are. 14. Power distributor according to one of claims 7 to I}, characterized in that the individual transformation sections such constructed and assembled or disassembled that they are individually with suitable adapters can be measured. 15. Power distributor according to one of claims 1 to 14, characterized by the series connection of several transformation arrangements. 16. Power distributor according to claim 8, characterized in that that the branch housing (24) as a longer line section, for example in the form of a Cable is executed. 030063/0615 : 928437 17. Power distributor according to claim 16, characterized, that the line section is designed as a transformer. 030063/0615