DE4205500C2 - Device for tracking a reflector antenna on a transmitter - Google Patents

Description

The invention relates to a device according to the preamble of the main claim.

Facilities of this type are known (see for example wise Microwave Scanning Antennas, R.C. Hansen, ACADEMIC PRESS, New York and London, 1964, pp. 165 to 169). The Diagram deflection or nutation around the reflector axis is, for example, by a lateral offset of a Exciter in relation to the reflector axis and through mechanical rotation of the exciter around the reflector axis achieved (conical scan), or by cyclical scanning of two or four at a distance symmetrical to the reflector axially arranged pathogens. That with this nutating Diagram received signal is stored when the Reflector axis from the signal incidence direction of the receiving station in the rhythm of the rotation modulated and the stronger the larger the shelf is. Via a tracking mecha assigned to the reflector In this way, nism can be controlled via a control loop Reflector axis are adjusted so that the amplitudes modulation goes to zero and then the reflector axis  coincides with the direction of signal incidence.

For the constant deflection of the reception diagram lobe based on their ε dB width, also as relative Designated deflection, it is necessary that the relative distance related to the wavelength a / λ (λ = current operating wavelength) constant remains. This is not the case with the known devices given, which limits their broadband.

It is also known to be the phase center of one Reflector antenna through so-called paracletic elements deflect (WO 82/04503). These are paracletic elements short dipoles related to the wavelength, from the outside can be wired in different ways and so reactances represent that do not absorb energy, however a shift in the phase center of the actual cause medium pathogen. The strict conditions for measuring the length of this short self not receiving Dipoles also restrict this known one Set up the bandwidth significantly.

It is an object of the invention to provide a device for carry a reflector antenna on a transmitter to create nutating diagram lobe in which the relative displacement of the main lobe in a large fre frequency range, for example over an octave frequency is independent.

This task is based on a facility Preamble of the main claim characterized by its characteristics solved. Advantageous further training he give themselves from the subclaims.  

The measure according to the invention makes the relative Distance a / λ kept constant, so that relative deflection of the reflector antenna frequency-independent pending, it can operate in a wide frequency range for example operated over an octave. The Facility according to subclaims 4 and 5 enables a particularly simple structure, as an additional Medium pathogen is superfluous and both the rotation of the phase center as well as the constant keeping the relative distance of the rotating phases center by cyclically switching from electronic Transmission links between the parallel  Pathogens is reached. The frequency dependent weighting the reception power of the individual pathogens can ver different ways are carried out, for example wise also through appropriately controlled intermediate ver stronger. It has been found to be particularly advantageous and simple however, proved to be simple frequency dependent for this To use attenuators, either because of their special dimensioning the desired frequency are dependent or have the corresponding tax facilities depending on the frequency in your Damping curve can be controlled according to frequency are.

The pathogens can be of any known type, for example simple or crossed dipoles, horn spotlights or the like depending on the application and Frequency.

The invention will now be described more schematically Drawings explained in more detail using exemplary embodiments.

Fig. 1 shows the side view of a reflector antenna, as it is suitable for example for satellite reception, with a reflector 1 and an exciter arrangement 2 arranged in the focal point of this reflector, which in the sense of the following figures is designed such that the distance a is laterally offset from the reflector axis 3 a phase center is formed which rotates at this distance a about the reflector axis 3 and thus generates a nutating reception diagram lobe 4 . This excitation arrangement 2 is connected on the one hand to the receiver 5 evaluating the received signal of a transmitter and also to a tracking device 6 , via which the mechanical adjustment device 7 for tracking the reflector 1 can be controlled depending on the amplitude modulation of the received signal generated by the nutation.

The FIGS. 2 to 5 show in plan view different possibilities for the inventive formation of these exciter assembly 2.

In the exemplary embodiment according to FIG. 2, two exciters A1 and A2 are symmetrically arranged on a single axis 8 , which runs transversely to the reflector axis 3 , at a distance d from the reflector axis 3 on both sides, in between an additional central antenna A _m on the reflector axis 3 arranged. According to the associated circuit diagram of FIG. 2, the two exciters A1 and A2 are connected via a changeover switch S to an attenuator D1, and the central exciter AM to an attenuator D2. The outputs of the two attenuators D1 and D2 are combined in a common output 10 which, according to FIG. 1, is connected to the receiver 5 or the tracking control device 6 . By cyclically switching between the two exciters A1 and A2, a receiving main lobe that changes from top to bottom is generated, specifically by a phase center P1 or P2, which arises from the interaction of the exciter A1 or the exciter A2 with the central exciter AM. The distance a between these phase centers P1 and P2 each from the reflector axis 3 is determined by the size of the received powers at the output 10 of the exciter A1 and AM or A2 and AM, the size of this received power is dependent on the size of the attenuators D1 and D2. If the two attenuators D1 and D2 have the same attenuation and the exciters A1, A2 and AM are of the same design, the phase center P1 or P2 is in the middle between the exciters A1 and AM or A2 and AM, the distance a is d / 2. If the received power at the output of the attenuator D2 becomes zero by appropriate dimensioning of this attenuator, then the distance a from the phase center P1 or P2 becomes d, the attenuation of the attenuator D1 is chosen so large that the received power at the output of D1 becomes zero, the phase center P1 or P2 lies in the middle on the reflector axis 3 , the distance a thus becomes zero. From this it can be seen that by a suitable choice of the attenuation curve of the attenuators D1 and D2 depending on the respective operating frequency λ the relative distance a / λ of the phase centers P1 and P2 can be kept constant. With a constant relative distance a / λ, the relative deflection of the main lobe is then frequency-independent.

Fig. 3 shows the application of this principle according to the invention in an exciter arrangement with four exciters A1 to A4 each arranged at a distance d and again with a central exciter AM on the reflector axis 3 , so here there are two opposing exciters with respect to the reflector axis 3 along a transverse axis 8 A1 and A3 and perpendicular to it along a second transverse axis 9 two opposing exciters A2 and A4 are provided, which in turn are cyclically scanned via a changeover switch S and connected to an attenuator D1 according to the associated basic circuit diagram. By cyclical switching between the antennas A1, A2, A3, A4, a rotating main lobe 4 is generated, the distance a from the associated rotating phase center P1 to P4 is in turn determined by the dimensioning of the attenuators D1 and D2, by appropriate choice of the attenuation curve of these attenuators depending on the frequency, the relative distance a / λ can again be kept constant.

If, for example, a reflector antenna in a broad frequency range with the center frequency λ _{o should have} a frequency-independent relative deflection, then by appropriately dimensioning the attenuators D1 and D2, a power ratio between the reception power L _{A of} the respective exciter A1 to A4 and the reception power L _M of the central exciter AM in the summation point 10 is selected in accordance with the relationship shown in FIG. 3; in a first approximation, the relative distance a _o and thus the relative lobe deflection is then constant.

Fig. 4 shows another possibility for the frequency-dependent shift of the phase center generating the main lobe and that without using a central exciter. Here, only two exciters A1 and A2, symmetrically opposite one another on an axis 8 with respect to the reflector axis 3, are provided, which are combined directly in an output 10 via attenuators D1 and D2. The damping value of these damping elements D1 and D2 is switched cyclically via a control circuit 11 assigned to the damping elements D1 and D2, if the damping value of the damping element D1 is greater than that of the damping element D2, the received power L1 is therefore less than L2, so the phase center P1 becomes in the direction of Exciter A1 shifted, in the opposite case (L1 is greater than L2), the phase center G2 is shifted downward in the direction of the exciter A2. In this way, the cyclical deflection of the main lobe can be generated by cyclically changing the damping values. At the same time, the amount of attenuation of the attenuators D1 and D2 depending on the frequency is chosen so that the relative distance a / λ of these phase centers P1 and P2 from the reflector axis 3 is constant in each case.

Fig. 5 shows the application of this principle to an exciter arrangement with four in a square at a distance to the reflector axis 3 arranged pathogens A1 to A4, which are in turn connected together via controlled attenuators D1 to D4 in the output 10. A rotating phase center P1 to P4 is generated by cyclically switching the attenuation values of the attenuators D1 to D4, the desired constant maintenance of the relative distance a / λ of these phase centers P1 to P4 from the reflector axis 3 being simultaneously achieved by corresponding frequency-dependent selection of these switched attenuation values The damping values of the four damping elements D1 to D4 required for the rotation of the phase center result from the table in FIG. 5, the amount of these damping values is dimensioned in the manner required for a / λ = constant.

Additional preamplifiers can be arranged between the individual exciters and the subsequent attenuators, as is indicated schematically in FIG. 5 by the amplification V. In the exemplary embodiment according to FIGS. 2 and 3, an isolating amplifier T is preferably arranged between the central exciter A _m and the associated attenuator D2, one output amplifier of which is connected to the attenuator D2 and the other output of which leads directly to the receiver 5 , in this way also when the transmitter is remote, a useful signal independent of the frequency modulation of the nutating lobe is evaluated in the receiver 5 .

FIG. 6 shows a further possibility for generating the rotation of the phase center P1 to P4 by cyclically switching the damping from damping elements D1 to D4 assigned to the exciters A1 to A4. For this purpose, the power of one of the pathogens A1 to A4 is strongly dampened compared to the others. If, for example, the power of the exciter A3 is strongly damped by the attenuator D3 and the power of the other three exciters A1, A2 and A4 is rated equally and less damped, the phase center P1 is shifted to the right by the distance a according to FIG. 6. By additional different union attenuation of the three exciters A1, A2 and A4 via the associated attenuators D1, D2 and D4, which in turn can be controlled via a control circuit 11 , this distance a can be increased or decreased, so that the required constant maintenance of a / λ can be reached. This arrangement has the advantage that the exciter diagram responsible for the reflector illumination is very little influenced by the measure according to the invention to achieve a / λ = constant.

Claims (9)

1. Device for tracking a reflector antenna ( 1 ) on a transmitter, in which the reception diagram ( 4 ) is deflected by cyclic scanning of at least two symmetrically spaced from the reflector gate axis ( 3 ) exciters (A1 to A4), characterized in that the exciters (A1 to A4, A _m ) are interconnected via the receiving power as a function of the frequency (λ) weighting transmission elements (D1 to D4) such that the relative distance (a / λ) of the phase center (P1 to P4 ) is constant. 2. Device according to claim 1 with two on one axis ( 8 ) transversely to the reflector axis ( 3 ) and laterally offset relative to the reflector axis exciters (A1, A2), characterized in that at the intersection of the two axes ( 3 , 8 ) Middle exciter (A _m ) is arranged and the laterally offset exciters can be cyclically connected in parallel with the central exciter via the receiving power as a function of the frequency-weighting transmission elements (D1, D2) such that the relative distance (a / λ) of the phase center thereby generated ( P1, P2) is constant ( Fig. 2). 3. Device according to claim 1 with four exciters arranged in a plane transverse to the reflector axis ( 3 ) symmetrically about the reflector axis (A1 to A4), characterized in that in the middle of these four exciters there is a central exciter (A _m ) and each of these four exciters with this medium exciter over the receiving power as a function of the frequency-weighting transmission elements (D1, D2) can be cyclically connected in parallel, such that the relative distance of the rotating phase center (P1 to P4) generated thereby is constant ( Fig. 3). 4. Device according to one of the preceding claims, characterized in that the frequency-dependent weighting of the reception power of the Exciter through frequency-dependent attenuators follows. 5. Device according to claim 4, marked net by using in the damping curve controllable attenuators. 6. Device according to claim 1 with two on one axis ( 8 ) transverse to the reflector axis ( 3 ) and laterally offset from this reflector axis arranged exciters (A1, A2), characterized in that the two exciters via controllable attenuators (D1, D2) connected in parallel are, a cyclic switching and frequency-dependent setting of the damping of these attenuators (D1, D2) an alternating phase center (P1, P2) can be generated, the relative distance (λ / 2) is constant ( Fig. 4). 7. Device according to claim 1 with four exciters arranged symmetrically about this reflector axis in a plane transverse to the reflector axis in the quadrilateral, characterized in that the four exciters (A1 to A4) are connected in parallel via controllable attenuators (D1 to D4), whereby by cyclical Switching and frequency-dependent adjustment of the attenuation of these attenuators, a rotating phase center (P1 to P4) can be generated, the relative distance of which is constant as a function of the frequency ( FIG. 5). 8. Device according to one of the preceding claims, characterized in that between Exciter and transmission power weighting the reception power supply elements each preamplifier (V, T) arranged are. 9. Device according to claim 2 or 3, characterized in that a separating amplifier (T) is arranged between the exciter (A _m ) and the associated transmission element (D2), one output of which is connected directly to the signal receiver ( 5 ).