DE1298590B - Microwave mixer head - Google Patents

Description

The patent application P 12 86161 :: 9-35 (German Auslegeschrift 1286 161) relates to a waveguide connector with four connections the electrical energy from one connection only to two of the remaining ones three connections is delivered and which consists of a waveguide section, in which are maintained by two dominant orthogonal oscillations progressing in the longitudinal direction of which the course of the electric field lines of one oscillation is symmetrical to an equipotential line, which is the field line and in which the other oscillation is generated in such a way that its electric field lines correspond to all of its equipotential lines a are symmetrical, and in the area in which the electric field lines of both potential lines are asymmetrical, and in the area in which the field lines of both Vibrations are directed in the opposite direction, decoupling means are provided.

The microwave arrangement corresponding to the main claim is it is in particular a mixing head in which the said decoupling means are designed as rectifier diodes. The waveguide section itself can be of round or square cross-section, and it can be laying down of the two orthogonal dominant waveforms, one that causes an asymmetry Extend conductor into the waveguide.

The additional invention is a microwave mixer head, which builds on the basic principles of the invention of the main patent application however, the coupling of one of the two microwave frequencies to be mixed by means of a waveguide and the other microwave frequency by means of an antenna-like one Conductor takes place, which protrudes into the waveguide section forming the mixing head.

The coupling of the two microwave frequencies to be mixed in using a microwave mixing head consisting of a waveguide section one waveguide for the one microwave frequency and one in the mixer head itself protruding conductor acting as an antenna is already through the French Patent 1241829 became known. The one for coupling the superimposition frequency provided, antenna-like acting conductor penetrates the .eine narrow side wall in the form of a waveguide section closed on one side of narrow rectangular Cross-section formed mixing head, during which to derive the intermediate frequency serving, from the merger point of the im. Mixing head provided outgoing diodes Head 'penetrates the top wall of the waveguide section forming the mixing head, that is, perpendicular to the antenna-shaped conductor coupling the superimposed oscillation runs.

In the case of a microwave mixing head consisting of a waveguide section, which in particular has an essentially square line cross-section, in which two progressive, dominant orthogonal oscillations are maintained via axial first coupling means and second coupling means provided on a side wall of the waveguide section, of which the course of the electric field lines of one oscillation is symmetrical is to an equipotential line of the field lines and the electric field lines of the other oscillation are asymmetrical to all of its equipotential lines, so that an area in which the electric field lines of both oscillations are in the same direction and an area in which the field lines of both oscillations are opposite is formed , and in both areas within the waveguide section one decoupling diode each in the longitudinal direction, aligned with one another from the walls of the waveguide section inward to form a common connection Extension point protrudes from which the intermediate frequency current dissipating conductor is isolated through the wall of the waveguide section in a direction that is perpendicular to the connecting line of the two diodes, according to patent application P 12 86161.9-35 (German Auslegeschrift 1286 161) is according to the invention as Means for adapting the coupling of the oscillation having the asymmetrical field component to the circuit carrying the mixed oscillation, an additional conductor extending from one side wall and directed towards the center of the mixing head and extending perpendicularly to the mixing diode arrangement is provided.

In the following description and the figures are appropriate Embodiments of the invention specified in more detail. Of the figures, FIG. 1 a schematic representation of the operation of an inventive with orthogoaalen Wave types of working microwave mixing head, FIG. 2 a perspective, partially broken representation of an embodiment of the invention, FIG. 3 shows a cross section corresponding to the section line 3-3 of FIG. 2, fig. 4 shows another embodiment the invention.

In Fig. 1 is a waveguide of square cross section with 1 designated; it is excited in two mutually perpendicular wave types, and although by .a vertically polarized wave, that of the horizontally arranged Waveguide 2 rectangular cross-section is fed, while a horizontally polarized one Wave generated by a local oscillator via the vertically arranged waveguide 3 rectangular cross section of the right side of the waveguide 1 is supplied. In this way, each of the supplied waves has a certain wave type.

In the waveguide 1, two are arranged in extension to one another Diodes 4 and 5 are provided which are connected to each other at opposite poles stand and with a horizontal conductor 6 for the output signal in Connected. The electric field of the signal wave is transmitted through the conductor 6 not disturbed and is connected to the crystal diodes 4 and 5 in the same direction, as indicated by the dotted arrows, coupled. The one from the local oscillator generated wave, however, is disturbed by the conductor 6 in such a way that the electric field in opposite direction with the two crystal diodes, like indicated by the full arrows, coupled. The difference of Currents in the two rectifier diodes flows via conductor 6 to a low-pass isolating choke6 ' on the rear wall of the waveguide and to the inner conductor of a coaxial conductor, which carries a beat wave generated by push-pull beat wave formation, where the current components in the two crystal diodes that on Noise from the local oscillator declines, each other in line 6 of the Break branch.

The object to be solved by the invention is to provide a favorable coupling of both the local superimposed and the signal wave with to achieve the mutually compensating diode rectifiers. Considered one first of all the signal wave, so there is an optimal adaptation of the signal wave conductive waveguide 2 with the crystal rectifiers 4 and 5 in that the Crystal rectifier near the jump point between the rectangular waveguide 2 and the essentially square waveguide section 1 are arranged, so that there is a zone of high electric field strength and the signal wave is fixed is coupled to the crystal rectifier because of the distance between the rectifiers and the right wall of the waveguide 1 is only a fraction of a wavelength and the same is a short-circuit level for the vertically polarized signal wave represents, so that there is a heavy load on the signal wave. After this in this way the coupling to the signal wave is chosen as well as possible, results there is a considerable mismatch between the one leading to the local overlay Waveguide 3 and rectifiers 4 and 5. This is due to the following reasons: Firstly, there is a jump point due to the gradual transition between the Waveguide 3 of rectangular cross-section and the waveguide 1 of square Cross-section; secondly, there is interference from the output line 6; third the local oscillator due to the diodes 4 and 5 is not very strong loaded because there is only a small distance between the diodes and the left side wall .The waveguide 1 is present, the left side wall as a short-circuit level for the horizontally polarized superimposed wave acts.

In the F i g. 2 and 3 an arrangement is shown in which the aforementioned Mismatching of the oscillator branch is largely eliminated. The waveguide section 1 square cross-section forms an opening in a metal block 1 ', the connecting flanges 10 and 11 for connection to the vertically polarized signal wave and the horizontally having polarized superimposed wave leading waveguide. The rectifier diodes 4 and 5 are placed in removable caps 12 which extend through the top wall surface and are screwed through the lower wall surface, and are split by a Cuff 13 held together at their inner ends. On the cuff 13 the conductor 6 is attached, which carries the intermediate-frequency output signal, the conductor 6 through an insulating low-pass choke 6 'in the wall of the waveguide is led; the conductor 6 forms the inner conductor of a coaxial conductor section 6 'for forwarding the intermediate frequency. Each cap 12 contains a filter network, which. the AC components of the crystal diodes to the one at ground potential held block 1 ', so that the DC components of the crystal rectifier at .. the execution points 14 can be monitored without thereby undesired Stray fields result.

The impedance matching of the waveguide leading to the local superimposed waveguide takes place in the following way: firstly, a rib 20 is provided on the right side wall of the waveguide 1, which extends from the outer surface of the flange 11 to a point in the vicinity of the conductor carrying the intermediate frequency 6 lies; Secondly, a pin 21 extends axially from the cuff 13 connecting the crystal diodes in an extension 2 'of the rectangular waveguide guiding the signal wave, this waveguide extending into the left end of the block 1' so that the pin 21 is protected against damage . The part of the rib 20 which is in the vicinity of the flange 11 adapts the supplied superimposed shaft to the waveguide section 1; that part of the rib 20 which is in the vicinity of the conductor 6 carrying the intermediate frequency adapts the disturbed wave type of the local superimposed to the crystal rectifiers 4 and 5. The rib can be beveled at the right end so that the most favorable transition from the waveguide leading to the local superimposed result is obtained, and the left end of the rib can also be beveled in order to make the coupling to the rectifiers 4 and 5 as favorable as possible design. The pin 21 forms a TEM resonator for the wave of the local superimposed, so that through it the effective short-circuit level is moved back into the waveguide carrying the signal wave and the load on the wave by the crystal detectors 4 and 5 is increased. In one embodiment of a mixing head according to FIGS. 2 and 3, the standing wave ratio was found to be less than 2: 1 within a frequency range of 4.9 to 5.9 kMHz, with no change in tuning. Since the adapter devices 20 and 21 lie essentially in a horizontal plane which passes through the center of the waveguide section of square cross-section and this plane is a neutral plane for the vertically polarized signal waves, these adapter devices essentially do not affect the signal wave at all.

It should also be noted that at the gradual transition between the waveguide section 2 ', which guides the signal wave, and the waveguide section 1 with a rectangular cross-section there is an inwardly directed shoulder 22, which represents an aperture. Through this aperture, the size of the Waveguide section of square cross-section can be adjusted so that a The most favorable possible adaptation to crystal diodes of normal size takes place. These Embodiment is more economical than one in which the special short-circuited Diodes are used. Furthermore, the larger areas of the terminals allow of these crystal diodes the use of a simple split cylindrical sleeve, in which, so that sufficient spring action takes place, given a considerable length have to be.

In another embodiment of a mixing head, the local oscillator is connected by means of a coaxial pin which penetrates the front wall of the waveguide 1 , the pin 21 extending into the waveguide carrying the signal wave and improving the coupling of the local oscillator to the crystal diodes.

In Fig. 4 shows an arrangement in which the inventive Mixing head an adjustable pin 30 in the form of a screw for adjusting the oscillator having, the screw 30 different deep through the left Wall can be screwed in and its longitudinal axis as an extension of the axis of the conductor 6 carrying the output signal is located. The screw 30 is screwed in so far, that, with a length of approximately d / 8, a maximum, painterly current flows through the crystal diodes results in what is determined at the terminals 14. With the adjusting screw set in this way there was a good match of the oscillator wave, namely a ratio of the amplitude the standing waves of less than 1.3, although this is only within a small one Frequency band of about 1%. The cause of this adjustment is apparently to be found in that the conductor 6 carrying the intermediate frequency has a high inductive jump point for the wave of the local superimposed, which forms by the capacitive reactance of the adjustment pin is compensated by creating a resonance on the crystal diodes 4 and 5 results. The signal frequency is in turn through this adjustment device not affected, as the adjustment device lies in the neutral plane. As practical Result of an arrangement according to FIG. 4 can be specified that the mixing head by means of the screw 30 over a frequency band of 20% to a ratio of the amplitude of the standing wave of less than 2% could be set. With another Embodiment was the adjusting screw 30 in addition to those in FIGS. 2 and 3 used adjustment devices 20 and 21, for the purpose of a Improvement of the coupling of the oscillation generated by the local oscillator with the crystal diodes without a deterioration in the usable bandwidth to draw on.

Considering the extremely small mismatch exhibited by both Input waveguides results, one can fully understand the received signal and the oscillation of the local oscillator.

It should also be noted that a branching arrangement that is similar that previously discussed, can be used as a, modulator by the: the Pin as an input terminal for the modulation frequency, causing disturbance of the waveforms serves and the opposite waveguide for feeding the carrier wave and to decrease the modulated output oscillation. An inventive The arrangement can also be used as a parametric amplifier by replacing the Diode rectifier acting as a consumer through voltage-controlled diode capacitance be used.

Claims (7)

Claims: 1. Microwave mixing head consisting of a waveguide section, which in particular has an essentially square line cross-section, in which two progressive dominant orthogonal oscillations are maintained via axial first coupling means and second coupling means provided on a side wall of the waveguide section, of which the course of the electric field lines of one The oscillation is symmetrical to an equipotential line of the field lines and the electric field lines of the other oscillation are asymmetrical to all of its equipotential lines, so that an area in which the electric field lines of both oscillations are in the same direction and an area in which the field lines of both oscillations are opposite, is formed, and in which in both areas within the waveguide section a decoupling diode in each case in the longitudinal direction aligned with one another from the walls of the waveguide section inward to form a common amen junction protrudes from which the conductor dissipating the intermediate frequency current is insulated by the wall of the waveguide section in a direction which is perpendicular to the connecting line of the two diodes, according to patent application P 12 86161.9-35 (German Auslegeschrift 1286 161), thereby marked that as a means for adapting the coupling-Jung of the oscillation having the asymmetrical field component to the circuit dissipating the mixed oscillation, an additional conductor extending from one side wall and directed towards the center of the mixing head and extending perpendicularly to the mixing diode arrangement is provided. 2. Mixing head according to claim 1, characterized in that the matching conductor consists of a pin (21). 3. Mixing head according to claim 2, characterized in that that the matching conductor consists of a screw bolt (30). 4. Mixing head after Claim 1, characterized in that the matching conductor consists of a flat rib (20) with a rib plane lying perpendicular to the diodes. 5. Mixing head according to claim 2, characterized in that the provided as a matching conductor Pin (21), starting from the diode junction, extends in the longitudinal direction of the waveguide that supplies a microwave frequency. 6. Microwave mixing head according to claim 5, characterized in that the pin (21) extends through a cover plate (22) extends into the microwave waveguide (2 '). 7. Mixing head according to claim 1 or one of the following, characterized in that the additional matching conductor (20) in parallel with the one deriving the mixing frequency from the diode junction Head (6) is arranged.