DE2339441C3 - Frequency-dependent coupling system - Google Patents

Description

will.

60 According to a further embodiment of the invention

it is provided that each coupling loop is essentially parallel to the inner wall of the cavity resonance

The invention relates to a frequency-dependent gate is arranged at a distance and that each coupling system consists of a thin flat conductor with at least one cavity resonance loop. iator through which the interconnected 65 The cavity resonator can be a circular inner conductors of two coaxial conductors are looped. or have a square cross-section, and the

An arrangement of this kind is from »Taschenbuch both coupling loops 1 can be along the Umier High frequency technology «, Meinkc-Gundlach. 1956, be arranged at the beginning of the cavity resonator that

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The vertical lines in the center of the cavity form an approximately right angle. Through this a particularly high level of freedom from feedback is achieved.

In a preferred embodiment of the coupling system according to the invention, the length of the Hesonance cavity in the natural direction of the Wave propagation selected so that it corresponds approximately to half the wavelength of the resonance frequency. Each coupling loop is roughly in the middle the end faces of the cavity resonator arranged so that an optimal coupling between the coupling loops and the resonant cavity.

The invention is illustrated below on the basis of exemplary embodiments with reference to Drawing explained in more detail; show it

1 to 4 are schematic representations of exemplary embodiments the coupling system according to the invention,

5 and 6 equivalent circuit diagrams of the invention Coupling system and

Fig. 7 shows the frequency characteristic of an embodiment according to the invention.

In FIG. 1A is a sectional top view of an embodiment of the invention is shown a cavity resonator 5 with the supply lines 1, 2, 3 and 4. Each of the feeders 1. 2, 3 and 4 consists of a coaxial line.

FIG. 1B shows a side sectional view along the line A-A ' in FIG. 1A. Thereafter, the cavity resonator 5 consists of a short piece of a waveguide, which consists of the four wall parts 6, 7, 8 and 9, which are closed by an upper and a lower end surface 10 and 11, respectively. The length of the wall parts 6, 7, 8 and 9 determines the resonance frequency of the cavity. The length of the cavity is equal to half the resonance wavelength, the transverse dimension of the waveguide is greater than half the length of the wavelength, so that the required type of oscillation is obtained inside the waveguide.

Since making a cavity resonator with sufficient dimensional precision encounters practical difficulties are in the neighboring cities Walls 8 and 9, the tuning plugs 12 and 13 are provided. Each tuning plug consists of one Ladder with a flat end that can be pushed more or less into the cavity. at Additional tuning plugs can be provided if required.

The coaxial conductors 1 and 2 are arranged on the wall part 6, and their inner conductors are connected to a coupling loop 14 connected, which consists of a thin, conductive sheet metal. Similarly, they are Coaxial cables 3 and 4 are arranged on the wall part 7 and connected to a coupling loop 15. The coupling loops 14 and 15 are spaced parallel to the walls 6 and 7, respectively, and from the walls electrically isolated. Thus, the inner cables of the coaxial cables 1 and 2 or 3 and 4 are in each case with one another connected and looped through the resonance cavity.

In normal operation, each of the Koaxialldtunuen 1, 2, 3 and 4, nut their characteristic impedance completed '· $ sen. It is not essential that the coupling loops 14 and 15 are arranged in adjacent wall parts; they can also be provided in opposite wall parts, as shown in FIG.

Instead of a hollow section with a square cross-section, the cavity resonator can also consist of consist of a waveguide piece with a circular cross-section, thus have a cylindrical shape. A corresponding embodiment of the invention is shown in FIG. Included the coupling loops 14 and 15 are arranged at right angles to one another.

F i g. 4 shows a further possible embodiment of the invention in which the coupling loops 14 and iS arranged diametrically opposite on a cavity resonator with a circular cross-section are.

On the basis of the exemplary embodiment in FIG. 4 2 is the type <lsr coupling between the four coaxial conductors 1, explained in more detail on the cavity resonator 5 3 and 4. FIG. The coaxial conductor 1 is insulated from the coaxial conductor 3 and the coaxial conductor 2 is insulated from the coaxial conductor 4. If energy is supplied to the resonance cavity via the coaxial conductor 1, the frequency of which does not correspond to the resonance frequency of the cavity resonator, the high-frequency energy is transmitted directly to the coaxial conductor 2 and dissipated through it. This also applies to a high-frequency signal which is fed in via the coaxial line 3 and discharged via the coaxial line 4 if it has a frequency deviating from the resonance frequency. If, however, a signal with the resonance frequency of the cavity resonator is fed in via the coaxial conductor 1, then this signal is coupled via the cavity resonator to the coaxial line 4 and discharged from it. In a similar manner, a signal that is coupled in via the coaxial line 3 can also be transmitted to the coaxial line 2. The mode of operation of this coupling system according to the invention can be explained by the fact that, in the case of resonance, circularly polarized waves are excited inside the cavity resonator, as follows with reference to FIGS. 4 will be explained. The high-frequency energy supplied through the coaxial conductor 1 causes a voltage between the coupling loop 14 and the resonator wall, which is reflected in the capacitance between the coupling loop

14 and the wall builds up. In the case of resonance, vibrations are excited in the cavity, which proceed as follows: that the electric field is perpendicular to the plane of the coupler, as with the excellent ones 1 line in F i g. 4 is shown. A voltage of the same size is generated in the corresponding coupling loop

15 induced on the opposite side of the resonance cavity. Dar corresponding equivalent circuit diagram is shown in Fig. 5, in the assembled the reactance of the cavity 5 of inductance and capacitances, the capacitances Cl and C will represent the capacitance between the coupling loops 14 and 15 with respect to the Resonatorwü'kI represents, represents C 1 the remaining total capacity of the Rcson;> nzhohlraums. If the two coupling loops and the two terminating resistors are identical, the circuit is symmetrical and the voltages appearing at the two F.ndcn are the same.

The current flowing in the coupling loop 14 in turn excites vibrations in the resonance cavity, whose electric field in the plane of the coupling

loop runs, as indicated in Figure 4 by the dashed lines. The associated equivalent circuit diagram is shown in Fig. 6. The coupling loops 14 and 15 are represented by the inductances L 2 and L 3. The total inductivity of the resonance cavity is given by the sum of the inductances Ll, L 2 and L 3. If the two coupling loops and the terminating resistors

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metric, and the chip ίο occurring at the ends voltages are the same. When the coupling loops are completed with the characteristic impedance of the coaxial lines are, then the two types of vibration that arise are also equal in terms of size and Oriented to one another in time and space so that a circularly polarized wave in the resonance cavity is maintained, with the resulting electrical vector revolving around the axis of the cavity turns.

It follows that the relative position of the two couplers to one another is not critical and that the coupling system according to the invention is like a directional coupler with variable sensitivity behaves, which is determined by the resonator characteristic. Those shown in FIGS. 1, 2 and 3 Embodiments behave similarly to that of FIG. 4, but with the in the F i g. 1 and 3 are preferred, since in these embodiments a direct coupling between the two coupling loops 14 and 15 is prevented and the coupling only via the induced, circularly polarized field takes place inside the resonance cavity. This results in improved isolation between the two couplers for frequencies other than the resonant frequency correspond. The coupling system has a constant resistance to the coaxial conductors 2 and 3, the value of which is independent of the frequency that is fed in via the coaxial conductor 1 and which, if the coupling loops are correctly dimensioned, does not contain any reactive components.

When the coaxial conductors 2, 3 and 4 are terminated with their characteristic impedance and a high-frequency source with a variable frequency is applied to the coaxial line 1, as in i-ig. 4 is shown symbolically, one obtains a transmission characteristic as shown in FIG. The transmission characteristic shows the change in the output power on the coaxial line 2 as a function of the frequency. At frequencies that are sufficiently far below the resonance frequency, the entire high-frequency energy that is fed in through the coaxial line 1 is transmitted to the coaxial line 2; the coupling within the resonant cavity is slight. If the frequency increases up to the resonance frequency of the resonance cavity (as indicated by the value R ), then all of the high-frequency energy is transmitted to the coupling loop 15 and passed on through the coaxial conductor 4. No energy is transmitted to the coaxial lines 2 and 3.

When the input frequency increases above the resonance frequency, the energy supplied to the coaxial line 4 is slowly reduced until. if the frequency is high enough, the entire high-frequency energy again through the coaxial line]: is discharged. Through careful construction and Matching the resonance cavity and the coupling can change the edges of the transmission characteristic in the range of the resonance frequency /? very steep Semacht. This results in a coupling system with a very high quality factor. The resonance frequency of the coupling system has the wavelength /., where /./2 is the length of the cavity resonator 5, as explained above.

The coupling system according to the invention can be used very advantageously for combining two signals, such as B. to combine a video carrier signal with the audio carrier signal in the output stage of a television station. The sound carrier frequency is applied to the coaxial conductor 1 of the cavity resonator 5, whose resonance frequency corresponds to the sound carrier frequency. The video carrier signal is transmitted via the coaxial line 3 supplied. The frequency difference of the carrier frequency of the tone b2: w. Image signal is sufficiently large so that the resonance cavity 5 is not excited to resonate by the image carrier frequency can be. This means that the picture carrier frequency remains unchanged through the coaxial conductor 4 is derived.

As explained in detail above, however, practically all of the energy that is passed through the coaxial conductor 1 is fed to the coaxial conductor 4, the output signal in the coaxial line 4 thus consists of the audio and video carrier signal and can be emitted directly via an antenna. The advantage of this coupling system according to the invention is that in practice none of the Coaxial line I energy supplied to the coaxial line 3 and vice versa none through the coaxial line 3 supplied energy is transmitted to the coaxial line 1. This allows a very good isolation between the sound and picture transmission systems can be achieved. Since this coupling system also has a constant resistance characteristic, the energy of the emitted signal does not change with frequency. The ones known so far Coupling systems of this type have been excessively bulky, complicated and expensive. As from the explanations above can be seen, a particularly advantageous construction is created by the invention, since the coaxial conductors 1, 2, 3 and 4 are relatively simple and compact and to the immediate Connection with associated circuit parts are particularly suitable.

By combining two or more cavity resonators with each other, transmission «.- characteristics get that complicated! are than those in FIG. 7 shown. For example surrender two coupled cavity resonators in each of which two. Arranging coupling loops are, two attenuation poles in the transmission characteristic, each of which is the resonance frequency of the two cavity resonators are assigned.

For this purpose 3 sheets of drawings

Claims (9)

S 344 and 345, known. In this case, a blocking filter is described which is connected in series in a co-axial line and which is 1. Frequency-dependent coupling system with we- stands through which the inner conductor of the coaxial line At least one cavity resonator through which the 5 is looped. interconnected inner conductors of two co- In high frequency technology are often Axial conductors are looped, thereby identifying coupling networks with frequency-dependent data, that both the coupling circuit as required, with those from one, a frequency mixture also the decoupling circuit of the coupling system each leading line em signal with a predetermined value decoupled from two coaxial conductors (1, 2; 3, 4) with io th frequency and onto another looped through, a coupling loop forming line can be transmitted. These circuits Inner conductors and that the coupling loops generally ideally have a constant (14, 15) insulates near the inner wall of the hollow input and / or output resistance, which is from Raumresonators (5) are arranged so that the frequency is independent and not a Bhndkompo level which contains coupling loops across the natural 15 nent. Coupling systems of this to can Direction of propagation through the coupling build up with coaxial lines, but are loops excited resonance waves. this requires diplexers that com- 2. Make the frequency-dependent coupling system complicated, bulky and expensive.
Claim 1, characterized in that the frequency-dependent coupling system of the two coupling loops (14, 15) described above can also be formed from waveguides and that the terminating resistors are constructed as described in US Pat. No. 2,999,988 of the coaxial lines are equal to each other. is. It is made from a rectangular waveguide, the 3. Frequency-dependent coupling system based on a mixture of signals with different Claim 2, characterized ^ characterized in that the frequency carries a signal with a predetermined Fre-KoaxUleituneen (1, 2;?, 4) with the wave frequency via a cavity resistance acting as a filter Are completed. resonator to a second, separate rectangular 4. Transfer the frequency-dependent coupling system to the waveguide. As is well known. Claim 1, characterized in that each are waveguides compared to coaxial conductors right Coupling loop (14, 15) essentially, parallel bulky, mechanically complex structures, which also to the inner wall of the cavity resonator (5) in the 30 are extremely expensive. Distance is arranged. The object of the invention is accordingly 5. Frequency-dependent coupling system according to it, a frequency-dependent coupling system Claim 4, characterized in that each create that is simple in construction and cheaper than Coupling loop (14, 15) made of a thin analog surface known from the prior art Head consists. 35 openings. 6. Frequency-dependent coupling system according to the invention this task is thereby common of the preceding claims, characterized in that both the coupling circuit and the characterized in that the cavity resonator (5) Auskoppelkicis of the coupling system each from two a circular or square cross-coaxial conductor with looped through, a coupling cut having. 40 loop-forming inner conductors and that the 7. Frequen.independent coupling system after coupling loops isolated near the inner wall of the one of the preceding claims, characterized in that the cavity resonator is arranged so that the characterized that the two coupling loops plane of the coupling loops transversely to the natural exit (14, 15) along the circumference of the cavity width direction of the resonator caused by the coupling loops (5) are arranged so that their mean 45 excited resonance waves lie. perpendicular in the center of the cavity a By these measures it is achieved that from form approximately right angles. a signal supplied via the coupling circuit 8. Frequency-dependent coupling ·. star after mixing with different frequencies the signal with One of the preceding claims, characterized in a frequency which is the resonance frequency of the characterized in that the length of the resonance cavity corresponds to 50, decoupled and cavity in the natural direction of the non-reactive transmission to the decoupling circuit about half the wavelength. corresponds to the resonance frequency. An expedient embodiment of the object 9. Frequency-dependent coupling system according to the invention is that the two coupling claim 8, characterized in that each 55 loops are identical and that the Ab-Koppelschlcifc (14, 15) roughly in the middle of the interconnection resistances of the coaxial lines, the end faces of the cavity resonator are the same. The coaxial lines can be advantageous (5) is arranged. liable to be terminated with the wave impedance