DE1591163B1 - Device for adding microwave signals - Google Patents

Description

The invention is based on a device for adding coherent microwave signals, preferably high performance, with a hybrid arrangement in the form of four arranged in a closed ring Hybrids.

An arrangement of four hybrids is known, each having two arms connected to two adjacent hybrids so that they form a closed ring. In the known arrangement, the hybrids of magic T are formed, their-symmetrical. H- and Ε-arms are connected to each other. This known hybrid arrangement has four inputs and four outputs and is used to form sum and difference signals as output signals from the four input signals fed to the various inputs. Such a hybrid arrangement is therefore suitable, for example, for combining the signals coming from the four elements of a monopulse antenna in the manner required for further processing.

In contrast, the invention is concerned with adding coherent microwave energy to that Purpose of receiving a microwave signal of increased power. So far in the development of Methods for such addition of coherent microwave energy encountered considerable difficulties. In a known method, a direct power addition of microwave signals was used tried using a number of directional couplers. However, when using directional couplers the power that can be transmitted is limited by the dielectric strength of the waveguide arrangements. One Another known method is to feed antennas over several lines. Here it is, however necessary to adhere to certain phase positions exactly, if there are no difficulties with the alignment of the antenna beam should occur, which result in an unsatisfactory function.

The invention is therefore based on the object of providing an improved device for adding coherent To create microwave signals that can transmit a higher average power than known devices without increasing or increasing the pulse power in any portion of the waveguide the duty cycle is reduced. Furthermore, in the device according to the invention, the control the phase of the signals to be added should not be critical, so that this device does not cause any problems the steering of the antenna beam causes.

This object is achieved in accordance with the invention with a device of the embodiment cited at the beginning solved in that the first and the second hybrid of the ring each have a first and second electromagnetic Distribute wave to a first and a second or a third and a fourth signal path, the third hybrids of the ring, the electromagnetic distributed on the first and third signal path Waves and the fourth hybrid see the electromagnetism distributed on the second and fourth signal path Combine waves into a first or second combined electromagnetic wave, that with the third and fourth hybrids of the ring non-reciprocal switching elements, the corresponding Form signal paths for the first and second combined electromagnetic waves, are connected and a second hybrid arrangement is furthermore coupled to the non-reciprocal switching elements, which divides the first and second combined waves. The arrangement according to the invention is particular suitable to combine the electromagnetic waves originating from two transmitters and the To use total energy with the help of the second hybrid arrangement to excite a monopulse antenna, without differences in the phase position of the two waves of the two transmitters having an influence on the directional diagram of the monopulse antenna.

Further details, configurations and advantages of the invention can be found in the following description can be seen in which the invention on the basis of the embodiment shown in the drawing is explained in more detail. It shows

F i g. 1 is a schematic circuit diagram of a device for adding microwave signals according to FIG Invention and

F i g. 2 is a diagram with a family of curves showing the loss of radiated power as a function represents the phase and / or power difference between two transmitters that have an inventive Feed device.

The circuit shown in Fig. 1 as an embodiment has two paths in which the two coherent microwave transmitters 24 and 25 added input signals supplied to each other and then fed to an antenna 23, which is a conventional monopulse antenna can. The coherent transmitters used can vary depending on the frequency and frequency required for the system Power consist of any number of common transmitters. Furthermore, any multiple of two Transmitters, such as four or six transmitters, are used according to the invention, depending on which output power is desired.

In order to achieve an optimal addition of power, the output signals of the transmitters must be coherent, ie that the output signals of the two transmitters must have a constant frequency and phase relationship to one another. To explain the F i g. 2, the input signals supplied to the device by the transmitters are denoted by Λ / Φ and B [0_. A device created and tested according to the invention worked in the K "band. The in F i g. The family of curves shown in FIG. 2 illustrates the results achieved with this device. The specific components mentioned in the following description were used to construct a device according to the invention for the K "tape. It will be understood, however, that devices for adding microwave signals can also be used in other frequency ranges, and the usefulness of such devices in other frequency bands, such as the X-band, could be demonstrated.

In the one shown in FIG. 1 upper path is a rotating assembly 11, which can be formed, for example, by a set of conventional rotary couplings, is provided, which receives its input signal from the transmitter A. The output voltage Α [Φ of the rotating assembly 11 arrives at a magical “T” 13, which is a common microwave hybrid. The magic "T" 13 receives its input energy at the Η-arm, to which the parallel arms are symmetrically connected, while the Γ-arm is provided with a terminating resistor. As a result, the hybrid for the input signal Α [Φ_ is reflection-free. As a result, the output voltages are

ORIGINAL INSPECTED

Findings of the magical "Τ" 13 both as indicated AI ^ PJjtL · In the lower path in Fig. 1, which contains a rotating assembly 12 and a magical "T" 14 , both of which are of the same type as in the upper path the same process takes place with respect to an input signal B / Q as shown in FIG. 1 is illustrated.

A second set of magic "T" 15 and 16 is used to add parts of the input signals Α / Φ_ and B / Q. The magic "T" 15 and 16 are also common microwave hybrids. The output voltage of the magic "Γ" 15 is just like the output voltage of the magic "T" 16

Α / 2 / _Φ + B / 2/0,

The output signals of the magic "T" 15 and 16 are each fed to one of two circulators 17 and 18. Circulators 17 and 18 are common non-reciprocal devices. The corresponding output signals of the circulators 17 and 18 are fed to the hybrids 19 and 20. The output signals of the hybrids 19 and 20 are then fed to the inputs 23 a to 23 d of the antenna 23. Furthermore, a hybrid 21 is connected between the circulators 17 and 18 and a further hybrid 22 between the hybrids 19 and 20 in order to create additional paths for electromagnetic waves. The hybrids 21 and 22 are also conventional components that are the same as the hybrids 19 and 20. The three output signals of the hybrids 21 and 22 are used to form the sum signal, the azimuth and the elevation error signal from the energy received by the antenna. Further details on common monopulse radar systems can be found in MI Skolnik's book, "Introduetion to Radar Systems," McGraw Hill Company, 1962, pp. 175-184.

It should be noted that the original input signals Α / Φ_ and B [0_ are divided and recombined in such a way that the illumination of the antenna is evenly distributed to both transmitters. A failure of one of the two transmitters or the circuits assigned to it only has the effect of reducing the total power supplied to the antenna. However, such a failure does not lead to a shift in the position of the beam transmitted by the antenna 23. Hence, any possibility of undesirable displacement of the beam emitted by the antenna is eliminated. Furthermore, this power combination technique limits the power in the waveguides to a value that never exceeds the peak power of the individual transmitters. The invention therefore enables the peak power emitted by the antenna 23 to be increased when using waveguides of conventional size in comparison with conventional devices for power addition. As stated earlier, any multiple of two transmitters can be combined according to the invention, so that there is an increased output power. The output signals of the transmitters can be divided and combined in the same way as A / jP and B / SL , so that the coverage of the antenna is evenly distributed to all transmitters.

The diagram according to FIG. 2 contains a family of curves which represent the losses of radiated power as a function of differences in power and / or phase between two transmitters A and B. Even if the diagram according to FIG. 2 reproduces the results which are reproduced in the coherent addition of the output signals of two power amplifiers operating in the K "band of a specific embodiment, it goes without saying that the invention is not restricted thereto, but can be used with the same advantage in connection with any power amplifiers in other frequency bands can find, for example, with two power amplifiers working in the X-band. The curves of the diagram according to FIG. 2 illustrate the effects of phase shifts between 0 and 90 ° between the output signals of transmitters A and B.

Since the upper and lower paths of the arrangement according to FIG. 1 are symmetrical, the output voltages of the circulators 17 and 18 are identical and equal to / 4/2 / Φ and B / 2 / 0_, while the voltage at the terminated outputs is equal to / 4 / 2 / Φ - ß / 2/0. is. From these equations it can be seen that with the same amplitude and a relative phase difference of 0 °, ie with A = B and Φ = 0, the output power at the connections 23c and 23d has the value {A / 2 + B / 2) ² = A ² , while the power loss at the connections (A / 2 - B / 2) ² = 0.

To further illustrate the invention, it is assumed that as a result of an error in a Rotary coupling, the power in the corresponding branch drops by 2 db and a phase shift of 30 ° arises. The effect of this error results from the following calculation:

Φ = 30 °:

B = 0.79 A ,

= 2db

V ₁₅ = V _i6 = y (I / O + 0.79 / JO)

= y (1.73Z13)

= 0.866 A / II, Pis = -Pi ₆ = 0.75 A ² ,
Loss of radiated power

0.75 A ²

= .1.25 db.

In the diagram according to FIG. A crossed point 2 indicates that when the power is reduced by 2 db as a result of a fault in one of the two transmitters or the circuit assigned to it with a phase error of 30 ° in the transmitted signal, a power reduction of only 1.25 db would occur.

As already mentioned above, instead of two, whole multiples of two transmitters can be sent to the Way, and it is possible to use the invention in all microwave frequency bands apply. Accordingly, the individual components can also be designed as is most favorable for the individual frequency bands.

Claims (2)

Patent claims: 1. Device for adding coherent microwave signals, preferably high power, with a hybrid arrangement in the form of four Hybrids arranged in a closed ring, characterized in that the first and second hybrids (13 and 14) of the ring each have a first and second electromagnetic Distribute the wave to a first and a second or a third and a fourth signal path, the third hybrid (15) of the ring distributed over the first and third signal path electromagnetic waves and the fourth hybrid (16) those on the second and the fourth Signal path distributed electromagnetic waves summarizes that with the third and fourth Hybrid (15 or 16) of the ring non-reciprocal switching elements (17 and 18), the corresponding Form signal paths for the first and second combined electromagnetic waves, are connected and furthermore with the non-reciprocal switching elements a second hybrid arrangement (19, 20) is coupled that divides the first and second combined waves. 2. Apparatus according to claim 1, characterized in that it has a first and a second rotating device (11 or 12) for receiving electromagnetic waves from a 20 speaking first and second microwave signal source (24 and 25) has that with one of the two rotating devices the first and the second hybrids (13 and 14) of the ring-forming hybrid arrangement is coupled, that the second hybrid arrangement has a fifth and a sixth hybrids (19 or 20) which feed electromagnetic waves to an antenna (23) and also dissipate them therefrom, so that a seventh hybrid (22) is arranged between the fifth and sixth hybrids in order to pass on energy received by the antenna, that between the third and fifth hybrids (15 or 19) a first circulator (17) is arranged, which supplies the fifth hybrid with electromagnetic waves and also removes them from it, that between the fourth and sixth hybrids (16 or 20) a second circulator (18) is arranged, which supplies the sixth hybrid electromagnetic energy and also removes it from it, and that between the two circulators (17 and 18) an ac hte hybrid (21) is switched on, which forwards the electromagnetic energy supplied by the antenna. 1 sheet of drawings