DE1020696B - Arrangement for adapting the inherent impedance of a maximum frequency tube to the characteristic impedance of a supply line - Google Patents

Description

The invention relates to an arrangement for adapting the input impedance of a high-frequency tube, especially sieve triode, to the characteristic impedance of a supply line using one with different wave resistance, adjustable in its resistance tranisformation properties, intermediate transformation line. An arrangement according to the invention can e.g. for amplifier, frequency conversion or frequency multiplication circuits can be used with advantage in the decimeter and centimeter wave range.

The general task of such circuits is to control the input impedance of the tube, i. H. the grid cathode impedance, to the characteristic impedance the supply line, which is generally a coaxial line, to adapt as well as possible to butt parts to avoid which energy reflections result and therefore impair the operation of the circuit.

The previous vocgescMagenm arrangements for transformation the input impedance of tubes of the high frequency technology on the characteristic impedance of the Supply lines have a coaxial structure, with the inner conductor and outer conductor with the input electrodes Tubes are electrically connected. The axis of the coaxial transformation arrangement falls generally coincides with the axis of the tube system.

Since the input impedance of the tube is within a certain. Frequency band to the characteristic impedance is to be adapted to the supply line, it is necessary to provide adjustable organs, which depending on the setting the input impedance of the tube for a certain frequency within this band adjust the wave impedance of the supply line. As voting bodies are z. B. Transformation slider is used, which is generally one length of 2/4, based on an average frequency of the required frequency band, have as capacitive shifters are formed and can be moved in the axial direction within the coaxial line.

In the known coaxial transformation arrangements is, however, the supply of the cathode or grid voltage, the heating voltage and the mechanical Drive device for the movable tuning members with a significant constructive Effort connected as these facilities are quite or partially inside the coaxial transformer arrangement must be located. The manufacturing tolerances of the individual construction elements must also be kept very small to the electrical The operation of the coaxial transformation devices not to be impaired.

The invention is based on the task of trans-arrangement
to adapt the self-impedance

a high frequency tube
to the wave resistance of a supply line

Applicant:
Siemens & Halske Aktiengesellschaft,

Berlin and Munich,
Munich 2, Wittelsbacherplatz 2

Claus Colani, Munich,
has been named as the inventor

formation arrangements regarding these difficulties to improve.

This is achieved according to the invention, starting from an arrangement of the type described in the introduction achieved that the transformation line from a parallel to one or more conductive There is strip conductor arranged on surfaces, which is interrupted at least at one point and at the separating point is designed such that the one strip conductor part ends in a pivot arm opposite the other strip conductor part, the end of which is formed like a ring segment, movable and capacitive with this is coupled.

It is known to use the decoupling transformer Train magnetron transmitter as a symmetrizing pot, whose on the earth-symmetrical side 'on A double line interrupted at one point also serves as an adjustable transformation line. The setting A certain transformation takes place there through disks, which increase the wave resistance of the double line change in a specific section. This leads to a very complex arrangement and has in addition, the disadvantage that only about a small. Transfornrationsbereich an opportunity is given. Furthermore, a transformer is known which consists of a quarter-wavelength line in the form of a circularly guided band, the is separated from outer conductors by dielectric disks. However, this transformer is not adjustable and also does not serve to solve the problem on which the subject matter of the invention is based.

709 809/249

The use of a ribbon line according to the invention allows compared to the comparable arrangements an adaptation of the input impedance of tubes of the high frequency technology, in particular of Disc triads, to the supply line with a low construction effort. The construction elements are easy to manufacture and can be assembled into a compact arrangement.

Another \ ^r orteil is the easy adjustability of Transformationsianordnung for a given frequency by turning the arm constructed as strip conductor part. The supply lines for cathode, grid and heating voltage can be led directly to the corresponding electrodes of the tube without the need for special structural measures in order to isolate them electrically and spatially from the transformation arrangement.

The invention is explained in more detail with reference to the drawing in FIGS. 1 to 5 of some exemplary embodiments explained.

1 is a schematic partial representation of a particularly simple embodiment. in the the principle of resistance transformation is clearly visible;

The strip conductor 6, 7, 8 is interrupted at least at one point, the separation point being designed in this way. that one strip conductor part 7, 8 ends in a swivel arm 7, which is opposite to the other strip conductor part, the end 6 of which is embodied in ringsegnientfärniig, is movable and capacitively coupled to it.

A structurally simple arrangement results when the strip line sections, as shown in FIG. 1, are oriented so that the part of the Bamd line whose strip conductor ends in the ring segment 6 over Contact springs, with the. Input electrodes of the tube is connected, while the part of the ribbon line, whose strip conductor ends in the swivel arm 7, is connected to the coaxial supply line.

The individual strip conductor parts are preferably designed so that the part of the strip conductor which lies between the input electrodes 2, 3 of the tube and the separation point of the strip conductor, a defined Characteristic impedance that is between the value of the wave impedance of the coaxial feed line and the input impedance of the tube. In contrast, the part of the band management which lies between the point of separation of the strip conductor and the coaxial supply line, preferably the

Fig. 2 shows the transformation path in the same transfer characteristic as the coaxial feed line.

mated pie chart;

Fig. 3 shows a preferred embodiment;

FIG. 4 shows a section along II-II from FIG. 3 dar while

Fig. 5 shows the corresponding cross section of a further embodiment, but this in longitudinal section corresponds essentially to FIG.

The disk triode 1 shown in the figures with the grid cylinder 2 and the cathode cylinder 3 is stored in a housing 4 which, for. B. contains the resonator forming the anode circuit and on the Cathode side is completed by the end wall 5 (Fig. 1). The input electrodes of the tube that in the illustrated, operated in a lattice-based disk triode by the cathode cylinder 3 and the lattice cylinder 2 are formed to a For this reason, the Ül> ergaing between, the Ribbon line and the coaxial feed line are not shown in Fig. 1, because it helps to understand the resistance transformation is not required.

The cross-sections of the individual strip conductor parts 6, 7, 8 can for example be slender rectangles, the longer sides of which face the conductive plane 9. In this case, the strip conductor part 6 is to be understood as a segment of an annular disc. The swivel arm 7, which is rotatable on the strip conductor part 8 and electrically is conductively attached, is preferably in one plane with the ring segment-shaped strip conductor H 7. Its narrower width means that the wave resistance

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Ribbon line connected to the coaxial feed line transforms. The ribbon line enables a resistance transformation in the simplest way in terms of construction the tube input impedance on the characteristic impedance of the coaxial feed line. Also the Feeds 19, 20 for the tube heating or the cathode voltage can, as shown in FIG. 1, can be brought up to the tube without special constructive measures.

The strip line consists of a strip conductor 6, 7, 8, which is configured differently in sections and which is arranged parallel to one or more conductive surfaces or planes. In Fig. 1 only one conductive plane 9 is shown, which lies parallel to the plane of the drawing and is connected to the end wall 5 of the housing 4 in an electrically conductive manner. The kit-end level 9 of the strip line ¹ has electrical input impedance contact via the housing end wall 5 and the built-in spring ring 11 with the grid cylinder 2 of the disk triode 1, while the strip line is electrically conductively connected to the cathode cylinder 3 via contact springs 10.

However, it is possible to provide further conductive surfaces or planes that coincide with the conductive plane9 are electrically connected. In the embodiment shown in Fig. 1, it is, for. B. λ-advantageous, to provide a second conductive plane parallel to the conductive plane 9 in such a way that the strip conductor 6, 7, 8 lies between these levels.

stood the part of the band management. the one from the tape ladders 7 and 8 and the conductive plane 9 is formed, is greater than the wave resistance of the ribbon line part, which is formed from the strip conductor 6 and the conductive plane 9. Even with a circular one Formation of the cross-sections of the individual strip conductors 6, 7, 8 can with appropriate dimensioning the desired resistance curve can be achieved. It is also possible to change the individual parts of the Form strip conductor 6, 7, 8 in cross-section differently, with the desired wave resistance curve also achieved by suitable dimensioning can be.

The transformation path of the input impedance of a tube of the highest frequency technology to the Characteristic impedance of the coaxial feed line is shown on the basis of a special exemplary embodiment in FIG. 2 shown in the transformed pie chart. The pie chart is based on the one selected in the example Characteristic impedance of the ribbon line part 6, 9 based on 35 ohms. The locus of the tubes in for a frequency band from 1.7 to 2.3 GHz, based on 35 ohms. is designated in Fig. 2 with 21, while 22 is the impedance at a for this example indicates the selected frequency of 2 GHz. As you progress on the ribbon line up to Koppelefoene I-I (Fig. 1) of the swivel arm 7 opposite the ring segment 6 you get in the circular diagram from point 22 to point 23. Depending on the setting of the pivot arm 7 means the remaining part of the ring segment 6 opposite the conductive one Level 9 has a different capacity, which is in the

65

Level I-I is effective as parallel capacitance. By this parallel capacity can be reached from point 23 in the Pie chart according to point 24. The series capacitance that occurs as a result of the separation point between the strip conductor parts 6 and 7 occurs, causes a transition from point 24 to point 25 in the circle diagram, the corresponds approximately to the characteristic impedance of the coaxial supply line, in this example 60 ohms. Since the ribbon line part 7, 8, 9, the one between the coupling point of the strip conductor parts 6 and 7 and the coaxial feed line has the same wave resistance as the supply line, no further transformation elements are required to be provided.

For any other frequency within the required frequency band, the swivel arm 7 (Fig. 1) set differently, so that the change in length of the ribbon line part between the input electrodes 2. 3 of the tube and the separation or coupling point of the strip conductor and the change in through the remaining part of the ring segment 6 opposite the conductive plane 9 formed a parallel capacitance Adaptation of the point given for this frequency on the locus 21 of the tube input impedance causes the wave resistance of the supply line.

As can be seen from Fig. 2, the Transformstionsweg for an arrangement according to the invention is in Pie chart very briefly showing broadband the arrangement is recognizable.

However, the embodiment described serves only for a more precise illustration and is in no way ^{limiting with regard to the structural design of the characteristic impedance ratios 1} and the width and position of the frequency band.

Fig. 3 shows a preferred embodiment of the present invention, which is particularly compact. Here, the conductive level of the ribbon line is divided into individual zones 12, 13, which are at right angles to each other. The strip conductor sections belonging to the individual zones of the conductive plane are also arranged perpendicular to one another. In this embodiment, one zone 12 of the conductive plane is perpendicular to the axis of the tube system and is advantageously formed by the end wall of the tubular housing 4, while the other zone 13 of the conductive plane is perpendicular to it and is advantageously formed by an extended side wall of the housing 4, if the housing 4 is cuboid. Correspondingly, the ring segment 6 and the swivel arm 7 of the ribbon line * lie parallel to the conductive plane 12, while the ribbon conductor part 14 is arranged parallel to the conductive plane 13. The dimensioning of the strip conductor part 14 is made so that the wave resistance of the coaxial supply line up to the separation or coupling point between the strip conductor share 6 and 7 is maintained.

In this embodiment, the coaxial one is used Supply line connected to the tape line in such a way that the outer conductor of the supply line is flanged to an angled extension 15 of the conductive plane 13, while the inner conductor of the supply line merges into the strip conductor part 14.

A coaxial connector 18 is preferably provided, on which the outer coaxial supply line, e.g. B. connected in the usual way by means of union nut can be.

Fig. 4 shows a section along the plane H-II of Fig. 3, wherein the strip conductor part 14 and the conductive plane 13 in section, the pivot arm 7 and the Ring segment 6 are shown in view. It can be seen that the conductive plane 13 in a simple Way designed as an extension of a side wall of the cuboid tubular housing 4 can be.

It is possible to provide further conductive surfaces or planes, which are advantageous with the conductive Level 13 have electrical contact and represent a protective housing for the strip conductor assembly.

Fig. 5 shows a corresponding section for a further embodiment, the longitudinal section in essentially corresponds to FIG. 3, which, however, has a circular outer boundary of the tube housing having. In this case, a cylinder jacket is particularly preferred instead of a conductive plane segment 17 is provided, which is preferably the extension of part of the outer boundary of the tube housing 16 represents. The band leader part 14 is dimensioned in this embodiment, that here, too, the wave resistance of the coaxial feed line up to the separation or coupling point of the strip conductor parts 7 and 6 remains. The further structural design of this example corresponds to Fig. 3.

Claims (7)

Claim R: 1. Arrangement for adapting the input impedance of a high-frequency tube, in particular Saheibentriode, to the characteristic impedance of a supply line using a wave impedance different in their resistance transformation properties adjustable, intermediately connected transformation line, thereby characterized in that the transformation line consists of one in parallel with one or more Conductive surfaces arranged strip conductor is interrupted and at least at one point is designed at the separation point in such a way that one strip conductor part ends in a swivel arm, the opposite of the other band conductor part, whose End is formed like a ring segment, movable and is capacitively coupled to it. 2. Arrangement according to claim 1, characterized in that the strip conductor formed as a ring segment (6) part with one of the input electrodes (2, 3) of the tube is electrically conductively connected and that the pivot arm (7) on the strip conductor part connected to the supply line ( 8) is attached rotatably and electrically conductive. 3. Arrangement according to claim 1 or 2, characterized in that between the separation point of the strip conductor and. the strip line part (7, 8, 9) lying on the supply line has the same characteristic impedance as the supply line, while the strip line part (6, 9) lying between the separation point and the input electrodes (2, S) of the tube preferably has a characteristic wave impedance of between the Characteristic impedance of the supply line and the input impedance of the tube. 4. Arrangement according to one of the preceding claims, characterized in that the conductive Area · or plane (9) of the ribbon line is divided into individual zones (12, 13) which are mutually are at any, preferably right angle, and that the individual strip conductor sections (6, 7, 14) lie parallel to the associated zones. 5. Arrangement according to claim 4, characterized in that that at least one zone (13) of the conductive den Ebenei as an extension of an outer wall a cuboid tube housing (4) is. 6. Arrangement according to claim 4, characterized in that that a zone (17) of the conductive surface as an extension of the outer wall of a cylindrical Tubular housing (16) is formed. 7. Arrangement according to one of the preceding claims, characterized in that the ribbon line with a bucket of coaxial supply line is bound that the outer conductor of the coaxial line is connected to a conductive surface or plane (9 or 13 or 17) is flanged to the strip line and the inner conductor merges into: the strip conductor (8 or 14). Considered publications:
German Patent No. 867,415;
German patent application P 7922 VIII a / 21 a ⁴ (published October 7, 1954). 1 sheet of drawings © 70S & 09/2 + 9 12.57