DE2533711B1 - CIRCUIT FOR COUPLING AND COUPLING OF ADDITIONAL SIGNALS WITH DIRECT RADIO SYSTEM - Google Patents

Description

The invention relates to a circuit for coupling and decoupling additional signals on the line equipment, in particular intermediate stations of radio relay systems, which are otherwise the transmission of many carrier-frequency interleaved channels or video signals, which the radio frequency carrier usually in Form of a frequency modulation are impressed, and are used in which additional signals in the receiver mixers both directions are supplied by modulation from their local oscillators.

In the case of directional radio links, in addition to the actual occupancy with message signals, the usual type, e.g. B. frequency-modulated to transmit additional signals such as business calls and control signals. For example, in a radio relay system for 1,800 speech channels, the sub-baseband range is from 0.3 to approx kHz reserved for 13 additional service channels with a bandwidth of around 3.1 kHz each and used for additional transmission.

At intermediate points without demodulation, the local oscillator is designed to be modulatable in order to be able to feed in the service signals. The additional signals are coupled out at a second intermediate frequency output of the receiver, which is followed by a demodulator. The transmission of the service signals must take place in both transmission directions, and it must also be received from both directions. This is shown in the block diagram according to FIG. 1, in which a receiver Ei receives such additional signals ZS from one direction and, after mixing, converts them into an intermediate frequency ZF , which in turn has a transmitter 51, in which an up-mixer is located, and an antenna for the radiation the radio frequency RF is supplied. The same applies mutatis mutandis to the reverse link, for which the transmitter and receiver are denoted by 52 and E2, respectively. The feed-in process in the receiver oscillators means that the fed-in signals are also decoupled at the own station. Your own eavesdropping and also acoustic crosstalk from the business call output 3 to the input ZS, d. H. a feedback occurs, which results in distortions and, in extreme cases, oscillation, ie the system for the transmission of the additional signals ZS becoming unusable.

The invention is based on the object of minimizing these distortions and the tendency to oscillate easy way to avoid and the other additional signals not coupled into your own station to be able to win as unaffected and decoupled from each other.

This task is performed with a circuit for coupling and decoupling additional signals on the line equipment, in particular intermediate stations of radio relay systems, which are otherwise the transmission of many carrier-frequency interleaved channels or video signals, which the radio frequency carrier usually in Form of a frequency modulation are impressed, and are used in which additional signals in the receiver mixers both directions are supplied by modulation from their local oscillators, solved according to the invention that in the receivers in both directions by demodulation corresponding Subbands of an electronic hybrid circuit received in the intermediate frequency path are supplied, in which an anti-phase cancellation of equal-frequency and in-phase components the two sub-bands takes place so that the remaining additional signals are obtained in pure form.

For this purpose, a circuit is advantageous in which the signal from one receiver (outward direction) is sent to one Transistor is led in base circuit and that of the other receiver (forward direction) to such in Emitter circuit and the collectors of the two transistors on one and the same terminating resistor, which is preferably followed by a post-amplifier, connected and in which the input resistances are also connected Both circuits by connecting parallel or series resistors to the same level are brought.

An advantageous development of this circuit is that of the two transistors downstream common amplifier stage in emitter circuit from their respective collector side Negative feedback paths to the emitters of the two pre-transistors are provided with which the Reinforcements of both ways are adjustable.

It is achieved in this way that the

ORIGINAL INSPECTED

Signals arriving from both channels at the same time are added in phase opposition in the hybrid circuit and be wiped out. Furthermore, the hybrid circuit, which is advantageously in electronic form of the above type is carried out, the advantage that the two inputs for the service signals are decoupled from each other.

The invention is illustrated below with reference to FIG. 1 and F i g. 2 explained in more detail.

The two signal outputs for the additional signals 1 and 2 in FIG. 1 are fed to the hybrid circuit G and at 3 the two signals are decoupled from one another and can be removed from their own component.

Since the realization of a coil fork, especially for larger frequency ranges, may be technical becomes difficult and impracticable, in many cases it is better to employ a circuit such as that shown in FIG F i g. 2 is shown in more detail.

The F i g. 2 shows a transistor circuit in which one signal 1 is fed to a transistor stage Ts 1 in a base circuit. The second signal 2 is fed to a second transistor stage 7s 2 in an emitter circuit. The collectors of both circuits are directly connected to one another and both circuits therefore have a common output resistance R 19 together with the input resistance of a further transistor stage Ts 3, which is provided for amplification and other tasks. The transistor Ts 3 is connected in the emitter circuit and the output for both signals then forms on Cll and R23 of node 3. In order to adjust the inputs of both circuits are completely different indeed because of their different characteristics to each other, located in the entrance of the base stage Ts 1 a resistor R 5 to increase the input resistance. In contrast, a parallel resistor R 14 is parallel to the input of the stage with the transistor Ts 2 in order to reduce its relatively high input resistance, to such an extent that both input resistances are brought to the same value Z.

By using a basic circuit on the one hand and emitter circuit on the other hand and the same gain In both ways it is achieved that in-phase components of the same level at the two inputs 1 and 2 disappear in the exit.

In order to increase the linearity and constancy of the system, there is also a negative feedback from the common output stage Ts 3 to both input stages. For this purpose, part of the output energy from transistor Ts 3 is fed back to the emitter side of transistor Ts 1 on the collector side via a variable resistor R 9. On the other hand, a voltage divider A20, C14, R 18 is implemented for feeding back a negative feedback voltage to the emitter of the transistor 7s 1 in parallel with its resistor R 17. The resistor R 18 is also designed to be variable in order to adjust the negative feedback in both branches to one another and to be able to set the same gain in both paths. A phase adjustment, which may be necessary for higher frequencies, can be carried out using variable dummy elements in the corresponding branches.

In this way, a very good decoupling of the type desired at the beginning can be achieved.

1 sheet of drawings

Claims (3)

Patent claims: 1.Circuit for coupling and decoupling additional signals on the line equipment, in particular intermediate points of radio relay systems, which otherwise serve the transmission of many interleaved carrier-frequency channels or video signals that are usually impressed on the radio frequency carrier in the form of a frequency modulation and in which additional signals in the Receiver mixers in both directions are fed by modulation from their local oscillators, characterized in that additional signals (1, 2) obtained in the receivers (Ei, E2) in both directions by demodulating corresponding subbands in the intermediate frequency path (ZF) are fed to an electrical hybrid circuit (G) , in which an anti-phase cancellation of equal-frequency and in-phase components from the two sub-bands takes place, so that the remaining additional signals are obtained in pure form. 2. A circuit according to claim 1, characterized in that the signal of one receiver (E 1) (outward direction) is fed to a transistor (Ts 1) in the base circuit and that of the other receiver (E2) (forward direction) one such in the emitter circuit (TS 2) and the collectors of the two transistors are connected to one and the same terminating resistor (R 19), which is preferably followed by a post- amplifier (Ts 3), that the input resistances of both circuits by connecting parallel ^ /? 14) or series resistors (RS) are brought to the same level. 3. A circuit according to claim 2, characterized in that negative feedback paths (R 9, R 20) to the emitters of the two pre-transistors (TSi, TS2) are provided with the common amplifier stage (TS3) connected downstream of the two transistors in emitter circuit from the collector side thereof which the gains of both ways are adjustable.