DE3920937C1 - Microwave signal generating circuitry - provides two signal components from circular polarised microwave signal in hybrid and supplied to separation filter - Google Patents

Abstract

The circuitry is designed to produce microwave signals in a common waveguide (E) which includes a hybrid (H), dividing a signal to be converted from a circularly polarised microwave signal into two signal components of equal and max. power. A polarising and distributing cross-over network (PW) with two inputs (1, 2) is supplied with the signal components. One output opens into a common waveguide, switching the paths so that the two parts are shifted by 90 deg. w.r.t. one another. In one of the separate paths a bridging guide (BW1, BW2) possesses a first hybrid (H1) which divides the signal part into two branches tuned to its frequencies by the units (F1, F2) and a second hybrid (H2) which combines the two branches, feeding them to the inputs of the distributing guide (PW). ADVANTAGE - Reduced power losses. Limited max. field strength.

Description

The invention relates to a circuit arrangement for Generate several different frequency bands and different polarizations associated microwave signals in a common waveguide according to the waiter Concept of claim 1.

Such a circuit arrangement is from DE-OS 27 47 632 known. The different frequency bands are separated here with the help of crossovers, which for each Frequency band have a blocking circuit.

The invention has for its object a Specify circuit arrangement of the type mentioned in the the lowest possible power loss arises and a lower maximum field strength occurs.

This task is the subject of Claim 1 solved. Advantageous embodiments of the invention are specified in the subclaims.  

That proves to be particularly advantageous Circuit arrangement when used in a satellite. Because the power loss and the maximum field strength should be like this be kept as low as possible, e.g. B. in a vacuum occurring multipactor effect (secondary electron effect) avoid.

Based on an embodiment shown in the drawing the invention is explained in more detail below.  

Fig. 1 shows a circuit arrangement for feeding linearly and circularly polarized signals in an antenna feed,

Fig. 1a shows an alternative circuit part to the circuit arrangement shown in Fig. 1 and

Fig. 2 shows a notch filter characteristic.

Generates the FIG. 1 to be extracted circuitry which both linearly and circularly polarized signals in a common waveguide is, for example, suitable for use in communications satellites. Because today's communications satellites are required to be able to transmit or receive signals from a large number of high-frequency channels simultaneously with an antenna. Due to international agreements, some of the high-frequency channels must be transmitted with linear polarization (horizontal and / or vertical) and another part with circular polarization (left and / or right-hand rotation). The common waveguide is an excitation horn E of a reflector antenna for this application. The excitation horn E receives linearly polarized signals and signal components from a polarization switch PW, which together form a circularly polarized microwave signal in the excitation horn E.

In the embodiment shown in Fig. 1, it is assumed that two horizontally polarized signals HP 1 , HP 2 and two vertically polarized signals VP 1 , VP 2 also belonging to different frequency bands are fed into the excitation horn E, and additional ones a left-handed (right-handed) circularly polarized signal is generated from another signal LP (RP) in the excitation horn. For this purpose, two bridge switches BW 1 and BW 2 are connected to two inputs 1 and 2 of the polarization switch PW. These two bridge switches BW 1 and BW 2 are constructed completely identically, since it is assumed here that the two horizontally polarized signals HP 1 , HP 2 are assigned to the same frequency bands as the two vertically polarized signals VP 1 and VP 2 . There are e.g. B. the two frequency bands 11 450-11 700 MHz and 12 500-12 750 MHz. The band 11 886-12336 MHz of the signal LP (RP) intended for circular polarization lies between these frequency bands.

The signal LP intended for circular polarization (RP) is first of all from a Hybrid H - here one as 3 dB- Coupler 90 ° hybrid - with two signal components shared benefits.

Each of these signal components reaches its own signal path to one of the two inputs 1, 2 of the pole switch PW. The BW 1 and BW 2 bridge switches already mentioned are switched into the two signal paths. The two bridge switches BW 1 , BW 2 are designed identically so that the two signal components formed by the hybrid H which are phase-shifted by 90 ° relative to one another at the excitation-side output of the pole switch PW still have a 90 ° phase shift. The desired circularly polarized signal is generated in the excitation horn E by superimposing the signal components of the same power that are phase-shifted by 90 ° with respect to one another.

Each bridge switch BW 1 , BW 2 has a first 90 ° hybrid H 1 , which divides the signal portion supplied to it into two signal branches provided with band-stop filters F 1 and F 2 in a power ratio of 1: 1. After the power components have passed through the signal branches, they are combined by a second 90 ° hybrid H 2 at its gate connected to the polarization switch PW to the original signal component.

Depending on which of the two inputs 3, 4 of the 90 ° hybrid H a signal LP or RP is fed in, this produces either a left-handed or a right-handed circularly polarized signal in the excitation horn E. The prerequisite for this is that the bridge switches BW 1 , BW 2 represent the same electrical lengths for the signal components emanating from the hybrid H up to the output of the polarization switch PW. If both inputs 3 and 4 of the hybrid are not assigned signals because only a circularly polarized signal of one direction of rotation can be generated, the unused input is closed with an absorber.

Via the bridge switches BW 1 and BW 2 inserted in the two signal branches, the two inputs 1 and 2 of the polarization switch PW are additionally supplied with linearly polarized signals HP 1 , HP 2 , VP 1 , VP 2 . In the exemplary embodiment shown, the crossover BW 1 transforms the horizontally polarized signals HP 1 , HP 2 into two different frequency bands, and the crossover BW 2 into the vertically polarized signals VP 1 , VP 2 , which lie in the same frequency bands as those orthogonal to them polarized signals HP 1 , HP 2 , forwarded to the pole switch PW. For this purpose, the linearly polarized signals HP 1 and HP 2 or VP 1 and VP 2 assigned to the two frequency bands are connected via a crossover W 1 or W 2 to a gate of the hybrid H 2 on the output side of the crossover BW 1 or BW 2 . It is the gate of the hybrid H 2 that is decoupled from the gate connected to the pole switch PW.

The hybrid H 2 distributes each of the linearly polarized signals HP 1 , HP 2 and VP 1 , VP 2 that are fed in to the two signal branches, each connected to two bandstop filters F 1 , F 2, with the same power components. Since these bandstop filters F 1 , F 2 are dimensioned such that they block the frequency bands of the linearly polarized signals HP 1 and HP 2 or VP 1 and VP 2 , the power components of the linearly polarized signals are reflected thereon and by the hybrid H 2 his gate connected to the polarization switch PW again summarized. Fig. 2 is shown in the filter characteristics of the band rejection filter F 1 and F 2. It shows that the blocking attenuation a has its maxima in the frequency bands 11 450-11 700 MHz and 12 500-12 750 MHz occupied by the linearly polarized signals HP 1 , HP 2 or VP 1 , VP 2 . Two bandstop filters F 1 , F 2 are connected in series in the signal branches of the bridge switches BW 1 , BW 2 , for example. The number of bandstop filters to be used generally depends on how many frequency bands with linearly polarized signals are to be transmitted.

The linearly polarized signals are reflected at the bandstop filters F 1 , F 2 . However, the signal components forming the circularly polarized signal are let through almost undamped. This means that the blocking circuits of the bandstop filters with their resonance frequencies lie outside the frequency band (11 886-12 336 MHz) of the signal to be polarized in a circular manner, so there is no significant excitation of the blocking circuits by this signal. Therefore, only a very small part of the power of the signal to be circularly polarized remains as power loss in the bandstop filters. This advantage is particularly important when the signal to be circularly polarized is of higher power than the linearly polarized signals. The power loss in the bandstop filters also remains very low because the high power of the signal LP, RP to be circularly polarized is evenly distributed over four signal paths (cf. FIG. 1). The low excitation of the blocking circuits by the high-power signal to be circularly polarized has the advantage that no very high high-frequency field strength arises in the blocking circuits. This counteracts the occurrence of "multipacting".

It is expedient to arrange the bandstop filter F 1 and F 2 so that the blocking circuit (each blocking circuit is tuned to a different resonance frequency) faces the hybrid 2 that has the lowest frequency dependence of the phase of the reflection factor for the frequency band to be reflected.

In addition to circularly polarized signals, should only signals of a single linear polarization - e.g. B. horizontal polarization - are transmitted, the circuit arrangement shown in Fig. 1 is simplified. Then the bridge switch BW 2 located between the input 2 of the polarization switch PW and the output gate 5 of the hybrid H can be replaced by the circuit part shown in FIG. 1a. This circuit section consists of the same band-stop filters F 1 and F 2 as they are in the remaining bridge switch BW 1 , and an all-pass filter L compensating for the running time of the bridge switch BW 1 , which in the simplest case is a line section. The all-pass L serves to compensate for the transmission phase of the hybrids H 1 and H 2 of the missing bridge switch BW 2 .

In a departure from the exemplary embodiment described, 180 ° hybrids or components with a similar effect can also be used instead of the 90 ° hybrids H, H 1 , H 2 . It is only necessary to ensure that the two signal paths from the feed point 3, 4 for circularly polarized signals LP, RP to the excitation-side output of the polarization switch PW produce a mutual phase rotation of 90 °.

If there is a difference in the transmission phase in the polarization switch PW itself between the input gates 1, 2 and the output gate , this fact must be taken into account when designing the bridge switches BW 1 , BW 2 . A predominant difference in the polarization switch of the transmission phase of 90 ° can be compensated for by the fact that the hybrid H is designed as a 180 ° hybrid (eg magic T) and the signal paths between this hybrid and the polarization switch PW have the same electrical lengths.

Each of the above-mentioned signals HP 1 , HP 2 , VP 1 , VP 2 LP, RP can in turn also be composed of several individual signals using a frequency and / or time division multiplex method.

The circuit arrangement shown in FIG. 1 was described above purely for a transmission mode. The same circuit arrangement can also be operated inversely as a receiver. It also enables mixed operation (sending / receiving).

Claims (6)

1. Circuit arrangement for generating several different frequency bands and different polarizations associated microwave signals in a common waveguide (E), which comprises a hybrid (H), which converts a signal into a circularly polarized microwave signal (LP, RP) in two signal components with the same possible power divides, as well as a polarization switch (PW) with two inputs ( 1, 2 ), to which the signal components are fed on separate signal paths, and with an output that opens into the common waveguide (E), and the two signal paths are connected such that the two signal components are 90 ° out of phase with one another at the output of the polarization switch (PW), characterized in that in each case in the signal path which is also fed with at least one linearly polarized signal (HP 1 , HP 2 , VP 1 , VP 2 ) Input ( 1, 2 ) of the polarization switch (PW) leads, a bridge switch (BW 1 , BW 2 ) inserted is switched, which has a first hybrid (H 1 ) which divides the signal portion provided for the formation of the circularly polarized microwave signal into two signal branches (F 1 , F 2 ) connected to the same frequency-selective means (F 1 , F 2 ) tuned to pass this signal portion, and a second hybrid (H 2 ), which combines the power components distributed over the two signal branches and feeds them to an input ( 1, 2 ) of the polarization switch (PW), and that the second hybrid (H 2 ) linearly polarizes the supply (s) supplied to it (n) Splits signal (s) (HP 1 , HP 2 , VP 1 , VP 2 ) between the two signal branches and their power components after reflection at the frequency-selective means (F 1 , F 2 ) which also blocks them, and the said input ( 1, 2 ) of the polarization switch (PW). 2. Circuit arrangement according to claim 1, characterized in that the hybrids (H, H 1 , H 2 ) are 3 dB directional couplers. 3. Circuit arrangement according to claim 1, characterized in that the frequency-selective means to the blocking (s) frequency (s) of the (the) linearly polarized signal / signals (HP 1 , HP 2 , VP 1 , VP 2 ) matched band-stop filter ( F 1 , F 2 ) and that as many bandstop filters (F 1 , F 2 ) are connected in series in each signal branch as there are linearly polarized signals (HP 1 , HP 2 , VP 1 , VP 2 ) with different frequency bands. 4. Circuit arrangement according to claim 3, characterized in that of the bandstop filters (F 1 , F 2 ) that side facing the second hybrid (H 2 ) which shows the lowest frequency dependence of the phase of the reflection factor for the frequency band to be reflected in each case. 5. Circuit arrangement according to claim 1, characterized in that in that signal path that has no bridge switch, because no linear polarized signal is fed via this signal path, a delay element ( 2 ) is inserted, which generates the same delay delay as the bridge switch in the other Signal path. 6. Circuit arrangement according to claim 1, characterized in that a 180 ° hybrid divides the circularly polarized signal (LP, RP) into two signal components and the polarization switch (PW) between their inputs ( 1, 2 ) and their output a difference in the transmission phase of 90 °.