DE1289561B - Parametric device, especially parametric amplifier - Google Patents

Description

The invention relates to a parametric device, in particular a parametric amplifier, for very short electromagnetic waves with a variable reactance, in particular a capacitance diode, consisting of a line branch, in the middle of which there is the variable reactance and in the case of one The supply for the pump energy takes place on the side and from another side here the supply of the signal energy and from a loaded resonance circuit with the Impedance behavior of a multi-circuit band filter for the idling frequency.

In the case of such parametric amplifiers, the most important thing is: with low-noise amplification, the product of the gain and bandwidth is as large as possible close. It is particularly important to use the bandwidth of the idling circle as much as possible large to measure. To do this, it is necessary to have multi-circuit filters for the idler circuit build up, which in the known designs from subdivided waveguide resonators exist and show a band filter behavior. However, it is particularly so with such multi-circuit filters very difficult, one also in terms of adaptation to the Impedance of the variable reactance, e.g. B. the capacitance diode, favorable rating too calculate and realize. In addition, multi-circuit filters are relatively difficult to match.

The invention is based on the object of circumventing these difficulties to implement a parametric amplifier, also a parametric converter or the like, which can be tuned in a very wide frequency band and is practical at the same time shows constant gain.

This task is done with a parametric setup, in particular parametric amplifier, for very short electromagnetic waves with a variable Reactance, in particular a capacitance diode, consisting of a line branch, in the middle of which there is the variable reactance and in the case of one The supply for the pump energy takes place from the other side the supply of the signal energy and from a loaded resonance circuit with the impedance behavior a multi-circuit band filter for the idling frequency, according to the invention thereby solved that the band filter behavior for the idling frequency by at least one appropriately tuned loaded waveguide resonator and one from the itself to the diode adjoining piece of the signal feed line existing coaxial line resonator is produced.

It is advantageous if the waveguide and / or the coaxial resonator, which together cause the band filter behavior for the idling frequency, multi-circuit are executed.

A very advantageous arrangement, particularly with regard to broadband consists in that the coaxial line resonator is designed as a 2/4 resonator and that the waveguide resonator is designed as a 7./2 resonator (the resonators can also be shortened or lengthened), in the middle of which the diode is located, to which, extending perpendicular to the waveguide resonator, the coaxial line resonator connects.

Especially with very short waves where the impedance of the diode would cause the resonators to be shortened too much, it is advantageous to if the coaxial line resonator is designed as a 2./2 resonator and the hollow conductor resonator is divided into two J / 2 resonators, in the middle of which the diode is arranged, and if the resonance frequencies of the two 2/2 waveguide resonators are symmetrical matched to the resonance frequency of the coaxial resonator for the idling frequency will. This makes it possible to achieve a particularly broadband design, the one three-humped band filter curve is approximated.

To block the pump and idler frequency from the signal line it is advantageous if following the A / 4 or A / 2 resonator for the Idling frequency blocking circuits can be arranged for the pumping and the idling frequency. Particularly advantageous designs for these trap circuits have been found in the outer conductor Grooves worked into the coaxial conductor proved to be about one deep Quarter of the associated wavelength.

In order to also make the signal circuit tunable to resonance, it is advantageous on the inner conductor of the coaxial conductor after the blocking circuits an axially displaceable Disc or an axially movable a / 4 transformer attached.

Variable short-circuit sliders have been used for the waveguide resonators proved to be very cheap for easier tuning.

About the damping necessary for energy absorption for the idling frequency to be able to vary the band filter independently of all other settings a device has proven to be very favorable, which consists in the fact that the variable Short-circuit pistons are pierced in the middle and through these holes from the outside axially displaceable rods are introduced, at least at their the resonator facing end consist of damping material. By more or less deep Immersing these rods with the damping material can reduce the loss resistance of the Resonators can be adjusted as required.

The invention is illustrated below with reference to exemplary embodiments and the F i g. 1 to 5 explained in more detail.

In FIG. 1 is the idling circuit of a parametric amplifier shown schematically with a waveguide resonator. The coaxial resonator consists from a part of the coaxial line 1 provided for signal feed with the inner conductor 4. The inner conductor leads directly to the variable real dance, in this case a varactor diode 5. perpendicular to the coaxial conductor for the signal feed Waveguide resonance chambers 2 and 3 arranged, each representing 2./4 pieces and together result in an A./2 waveguide resonator. The diode is thus in series to the coaxial conductor and arranged parallel to the waveguide. The feed line -for the pump energy is not shown in this picture; she can have one to both resonator arrangements are carried out perpendicularly extending waveguide. The whole The arrangement consequently forms a branch, in the center area of which the diode 5 is arranged. In this example, the idler frequency is selected to be so low that the diode impedance becomes very large. Therefore, the resonance tuning of the Diode necessary impedance both with a short-circuited a / 4 coaxial line as well as with two short-circuited d / 4 hollow lines connected in parallel. These two waveguide sections 2 and 3 thus form a 2/2 resonator. if for both resonators equal wave resistances are assumed, the bandwidth of the A / 4 coaxial resonator is 2 times larger than that of the A / 2 waveguide resonator. Physically this can be explained by the fact that the A / 2 waveguide resonator has a much greater energy storage than the A / 4 coaxial resonator. The two resonators together result in a band filter behavior, which increases the bandwidth is increased by at least a factor of 3 with the same power gain. One can Increase the bandwidth even more by having both the coaxial line resonator as well as the waveguide resonator by introducing screws, diaphragms or the like. divided into several resonance chambers and tunes the individual resonators in such a way that that the flat and broadest possible resonance curve for the idling frequency is created.

The lower part of FIG. 1 shows schematically a plan view the arrangement, by means of the dashed lines the field lines that are used for coupling of the two resonance spaces are indicated. Becoming beneficial, as in the F i g. 1 not particularly shown, the two waveguide resonators through Short-circuit slide designed to be tunable. Then to the A / 4 coaxial resonator a low-pass filter for the signal frequency is expediently in the signal feed line arranged, which blocks the waves of idler frequency and even higher frequencies. However, it is also possible to use an arrangement as explained later in the case of FIG F i g. 5 can be seen.

Since the impedance of the diode decreases with increasing idling frequency and so that the resonators get shorter and shorter until they finally don't can realize more, one is forced to use the resonators at high idling frequencies designed as A / 2 resonators. Such an arrangement is shown in FIG. 2 schematically shown. The coaxial resonator 1 is designed as an A / 2 resonator, and likewise it is the two waveguide sections 2 and 3, so that in this embodiment result in three interconnected resonance circuits for the idling frequency. the Resonators can of course also be shortened or lengthened electrically. It has proved to be useful, the two cavity resonators 2 and 3 symmetrically to match the resonance of the coaxial line resonator 1. The lower part of the F i g. 2 again shows the field image. The bandwidth of the A / 2 coaxial resonator is, if again the same wave resistances are assumed, not greater than that of the J / 2 waveguide resonators. The aforementioned triple vote allows A gain characteristic can be achieved which corresponds to the resonance curve of a three-circle Corresponds to the band filter.

The F i g. To clarify this situation, 3 shows the electrical Equivalent circuit diagram of this dreikreisiaen Idlinakreis according to Fig.2. Z1 and Z2 mean the impedances of the waveguide resonators and Z3 that of the coaxial line resonator. Since there is also the variable reactance in series with the coaxial resonator, in this case one Capacitance diode. is the approximate equivalent circuit diagram of this diode in the figure shown within the dashed rectangle. The resistors R 1 and R 2 are the loads that the two waveguide resonators 2 and 3 for the idling frequency exhibit. They are in the scheme of FIG. 2 by the filled triangles R 1 and R 2 indicated. In FIG. 4 is the three-circle belonging to this arrangement Locus curve of the impedance of this arrangement for the idling frequency is shown. the Impedance is seen from and corresponds to the junction of the varactor diode a three-humped gain characteristic. To a maximally flat setting to achieve, must at a given load of the waveguide resonators certain detuning of the resonators can be set. The achievable bandwidth within certain limits, the greater the load, the more the waveguide resonators are loaded are. However, this also increases the rate at the junction of the capacitance diode resulting negative resistance, so that ultimately the noise of the amplifier would increase.

The to the arrangement according to F i g. 1 associated electrical equivalent circuit is obtained if in FIG. 3 the series resonance circuits through parallel resonance circuits be replaced. The parallel-connected reactances of the two V4 waveguide resonators in FIG. 1 can then be combined to form a parallel circle, so that only a two-circle Idling circle is created.

An embodiment according to the scheme of FIG. 2, which has proven to be particularly effective and broadband in practice, is shown in FIG. 5 shown. It shows the cross section through a parametric amplifier for the frequency 6 GHz, which has a three-circle idling circle. The amplifier works with a capacitance diode to which a pump frequency of 36 GHz is fed. The diode 1 is mounted in the branch point of a T-shaped waveguide with the cross section 3.5 X 7 mm. The pump energy at the frequency 36 GHz is supplied to the branch via the third waveguide arm, not shown, which runs perpendicular to the plane of the drawing. In this waveguide for the pump frequency feed line, a filter is attached that only allows the pump energy to pass, but practically represents a short circuit for the idling frequency, which is 6 GHz lower than the pump frequency. The signal frequency f 1 is fed in via a coaxial line 2. On the inner conductor of this coaxial line there is a capacitive disk 3, which can be displaced along the line, to tune the signal circuit. Further towards the diode there are radial grooves 4, 5 in the coaxial conductor, which have a depth of about 1/4 of the associated frequency. and which serve as blocking circuits for the pump frequency (4) and for the idling frequency (5). The idling trap circuit 5 closest to the diode, together with the diode and the short coaxial line section lying between them, forms a resonator for the idling frequency, which corresponds to the coaxial i2 resonator in FIG. 2 corresponds.

The waveguide sections 6 and 7, which are approximately A / 2 long, are also in resonance with the diode at the idling frequency. Their resonance frequencies are shifted symmetrically to that of the coaxial resonator. The waveguide resonators 6 and 7 can be additionally loaded by pins made of damping material, which dip through the short-circuit slide 8 and 9 into the resonators. This arrangement has the advantage that the resonance position can be shifted by means of the short-circuit slide and, independently of this, the necessary loading of the resonators can be adjusted by axial movement of the pins 10 and 11. In FIG. 6 is the measured gain characteristic of an arrangement according to FIG. 5, in which one can clearly see the resonance of the coaxial resonator in the middle and, symmetrically to it, the resonances of the waveguide resonators. The gain-bandwidth product is about 1500 MHz. In contrast, when coordinating with only one waveguide resonator, a gain-bandwidth product of 400 MHz was measured, and when coordinating with the coaxial resonator alone, a product of 500 MHz was measured. It must be taken into account that the measured gain-bandwidth products were limited by the bandwidth of the signal circuit, so that when this bandwidth is increased with the arrangement according to the invention, even larger gain-bandwidth products can be achieved.

Claims (7)

Claims: 1. Parametric device, in particular parametric Amplifier, for very short electromagnetic waves with a variable reactance, in particular a capacitance diode, consisting of a line branch, in whose central area is the variable reactance and above that from one side the supply for the pump energy takes place here, the supply from another side the signal energy and from a loaded resonance circuit with the impedance behavior a multi-circuit band filter for the idling frequency, characterized in that that the band filter behavior for the idling frequency by at least one corresponding tuned loaded waveguide resonator and one from which to connect to the diode subsequent piece of the signal feed line existing coaxial line resonator is produced. 2. Parametric device according to claim 1, characterized in that that the waveguide and / or the coaxial resonator, which together the band filter behavior for idling frequency, are multi-circuit. 3. Parametric setup according to claim 1, characterized in that the coaxial line resonator is an A / 4 resonator is designed and that the waveguide resonator is designed as an A / 2 resonator, in the middle of which there is the diode, which is perpendicular to the waveguide resonator extending, the coaxial line resonator connects. 4. Parametric setup according to claim 1, characterized in that the coaxial line resonator is an A / 2 resonator is formed and the waveguide resonator consists of two A / 2 resonators, in the center of which is the diode and perpendicular to this the coaxial line resonator. 5. Parametric device according to claim 4, characterized in that the coaxial line for supplying the signal energy towards the source of the signal energy blocking circuits for the pump and for the idler frequency, which are preferably made up of A / 4 resonators exist in the outer conductor of the coaxial conductor (A is the pump or the Idler frequency associated wavelength in the coaxial conductor). 6. Parametric setup according to one of the preceding claims, characterized in that on the inner conductor of the coaxial conductor used to supply the signal energy is an axially displaceable one Disc is attached, with which the signal circuit can be tuned to resonance. 7th Parametric device according to claim 5 or 6, characterized in that the Resonance frequencies of the two A / 2 waveguide resonators for the indling frequency is tuned symmetrically to the coaxial resonator for the idling frequency. B. Parametric Device according to one of the preceding claims, characterized in that one or the two, optionally subdivided waveguide resonators for the idling frequency are completed by variable short-circuit slide, in which axially displaceable, at least partially consisting of lossy material Rods are provided with which by more or less deep immersion in the Waveguide resonators the load on the waveguide resonators is adjustable.