DE1283913B - Circuit arrangement for receiving amplitude-modulated signals transmitted over lines with a high interference level, in particular telecontrol signals transmitted over high-voltage lines - Google Patents

Description

Interference voltages, especially broadband interference voltages, like them occur in the carrier-frequency transmission of messages on high-voltage lines, at the input of a filter cause a signal at its output that is similar to that of a The resulting amplitude modulation is similar. So occurs in a communication system with amplitude modulation at the input of the receiving filter an interference voltage, see above this is evaluated as a signal at the output of the filter, and this leads to errors, especially when transmitting teletype and telecontrol pulses. It will simulated pulse telegrams if the interference level is in the order of magnitude of the Useful level or greater.

The reason why the interferences at the output of the receiving filter have a pulse-shaped character is that, as can be seen from FIG. 1 shows that the filter subjected to broadband interference voltages must oscillate according to the changing phase position of the interference frequency contained in the interference voltage, the amplitude of the interference voltage at the output of the filter becoming zero at the time of oscillation. At the points where the phase of the interference frequency changes, those in FIG. 1 illustrated nodes 0, 1, 2, 3 and 4.

It is known to determine the level of the interference level and, if this exceeds a certain level, to prevent the evaluation of the received signal (German interpretation documents 1080 806 and 1202 311).

It is also known to select the desired code accordingly to distinguish from the irregular impulses generated by disturbance (»remote monitoring and remote control "by K. Bart e1s, edition 1964, p. 30, paragraphs 1 and 2, and p. 40, Paragraph 2).

The disadvantages of the known circuits are as follows: From entering the disturbance is up to its detection and up to the prevention of the evaluation a certain amount of time is necessary. During this time, a malfunction can already occur incorrect telegram must be evaluated.

The invention which avoids these disadvantages relates to a circuit arrangement for receiving amplitude-modulated signals transmitted at carrier frequencies via lines with a high level of interference Signals, in particular from remote control signals transmitted via high-voltage lines.

According to the invention, a switch is connected upstream of the reception filter, the comparison frequency that is identical to the carrier frequency and is in phase is controlled and the disturbed received signal only if it is in phase switches through with the comparison frequency.

The invention is based on the basic idea that in order to form the in FIG. 1 to avoid nodes (amplitude dips) of the filter output voltage caused by the interference voltage, the filter must not be subjected to interference voltages with changing phase positions. In particular, only that interference frequency that has the same phase position as the carrier frequency of the useful signal may pass in the pass band of the filter.

The invention is illustrated with reference to FIGS. 2, 3, 4, 5 and 6 explained in more detail. In Fig. 4 is at a) the switch 9 with the two input terminals 5 and 6 for the received useful signal U 1 and the pending interference signal U 2 in the event of a fault, the control terminals 7 and 8 for the supply of the frequency and useful signal in-phase comparison voltage U 3 and the output terminals 10 and 11 at which the useful signal U 4 switched through in the correct phase is tapped.

Furthermore, at b) it is shown how a one in phase with U3 switched-through useful signal U 1 is present as signal U 4 at the output of the switch, while at c) it is shown how an interference signal U 2 in phase opposition to U3 is the same Frequency is not switched through by the switch and consequently at the output of the Switch the voltage U 4 - 0 is present.

Finally, with d) a mixture of the useful signal U 1 and a frequency of the useful signal and the interference signal U phase different example, noise) is 2 (e.g., displayed, wherein after switching through means of U 3 at the output terminals 10,11 of the switch only with U 3 in -phase components of U 1 and U 2 are pending.

The signal U 4 is sent to a receive filter. That at the exit The signal obtained from the receiving filter is shown in FIG. 2 shown. In contrast to the one shown in FIG. 1, the amplitude never goes to zero. By Residual ripple caused by interference can be cut off by means of a limiter and the received signal is then corresponding to FIG. 3 as a signal more constant Amplitude available. It is a pretense of a pulse telegram due to a malfunction avoided.

The in F i g. 4 schematically illustrated switch 9 can, for. B. accordingly F i g. 5 or 6 are executed.

The electronic switch according to FIG. 5 has an input transformer 12 with a primary winding W 1 charged by the received useful voltage and two secondary windings W 2 and W 3 with the same number of turns and an output transformer 13 with a primary winding W 4 and a secondary winding W 5 for picking up the switched useful signal. One end of the secondary windings W 2 and W 3 of the input transformer are each connected to one end of the primary winding W 4 of the output transformer via the collector-emitter path of one of two complementary transistors 14 and 15, and the other ends of the secondary windings of the Input transformers are each connected to the other end of the primary winding of the output transformer via a diode 20 or 21 which is permeable in the forward direction of the associated collector-emitter path. The bases of the transistors 14, 15 are connected to the tapping points of two voltage dividers 16, 17 and 18, 19, which are connected in parallel to the input terminals 7, 8 for the controlling comparison voltage. The comparison voltage is expediently obtained by filtering off the carrier frequency from the received useful signal by means of an appropriate filter.

The mode of operation is as follows: Is the comparison voltage potential the terminal 7 is positive compared to that of the terminal 8, so the transistor 14 becomes conductive and the transistor 15 blocked. The half-wave of the useful voltage at which the Terminal 6 carries a positive potential compared to terminal 5, is generated by the secondary winding W 2 transmitted via transistor 14, diode 20 and winding W 4 to winding W 5, but during this transmission path for the other half-wave of the useful voltage through the transistor 14 and the diode 20 is blocked.

If the comparison voltage potential of terminal 7 is negative compared to that of terminal 8, transistor 15 becomes conductive and transistor 14 is blocked. The half-wave of the useful voltage, at which terminal 6 has negative potential compared to terminal 5, is transmitted from secondary winding g'3 via transistor 15, diode 21 and winding W 4 to winding W 5 , while this transmission path is used for the other Half-wave of the useful voltage is blocked by the transistor 15 and the diode 21.

The transistors 14 and 15 each switch a half-wave of the Useful voltage through. If there is no comparison voltage, both transistors block. An uncontrolled flow of current is established through the diode 20 or 21 via the collector-base paths of the transistors 14 and 15 and the voltage divider resistors 17 and 19, respectively.

The electronic switch according to FIG. 6 has an input transformer 22 with a primary winding W 6 to which the received useful signal voltage is applied and two secondary windings W 7, W 8 with the same number of turns and an output transformer 23 with a primary winding W 9, W 11 having a center tap and a secondary winding W10 for picking up the switched useful signal. One ends of the secondary windings W7, W 8 of the input transformer are each connected to the center tap of the secondary winding W 12, W 14 of an additional control transformer 28 and also to the primary winding of the via the collector-emitter path of one of two transistors 24, 25 of the same conductivity type Output transformer connected. The other ends of the secondary windings W 7, W 8 of the input transformer are each connected to the ends of the primary winding of the output transformer 23 via a diode 26, 27, the forward direction of which corresponds to that of the collector-emitter path of the associated transistors 24, 25. The bases of the transistors 24, 25 are connected to the outer ends of the secondary winding W 12, W 14 of the control transformer 28, the primary winding W 13 of which is connected to the input terminals 7, 8 for the controlling reference voltage.

The mode of operation of the circuit is as follows: If the comparison voltage potential of terminal 7 is positive compared to that of terminal 8, transistor 25 is made conductive via windings W 13 and W 14 of control transmitter 28 and the transistor is made conductive via windings W 13 and W 12 24 blocked. The half-wave of the useful voltage, at which terminal 5 has a positive potential compared to terminal 6, is transmitted from winding W 6 to winding W 8 and from there via transistor 25, diode 27 and winding W 11 to winding W 10 , while this transmission path for the other half-wave of the useful voltage is blocked by the transistor 25 and the diode 27. If the comparison voltage potential of terminal 7 is negative compared to that of terminal 8, transistor 24 is made conductive via windings W 13 and W 12 and transistor 25 is blocked via windings W 13 and W 14. The half-wave of the useful voltage, at which terminal 5 has negative potential compared to terminal 6, is transferred from winding W 6 to winding W 7 and via transistor 24, diode 26 to winding W 9 and from there to winding W. 10, while this transmission path for the other half-wave of the useful voltage is blocked by the transistor 24 and the diode 26.

The transistors 24, 25 thus each switch a half-wave of the useful voltage by. If there is no comparison voltage, both transistors block. Through the diode 26 or 27 is an uncontrolled flow of current across the collector-base path the transistors 24 and 25 prevented.

Claims (4)

Claims: 1. Circuit arrangement for receiving via lines Amplitude-modulated signals transmitted with a high level of interference, in particular of telecontrol signals transmitted via high-voltage lines, thereby characterized in that-the reception filter is preceded by a switch (9) which is operated by one of the carrier frequency equal and in-phase comparison frequency controlled and the disturbed received signal only if it is in phase with the Comparison frequency switches through. 2. Circuit arrangement according to claim 1, characterized in that the switch is an electronic switch which has an input transformer (12) with a primary winding (W1) acted upon by the received useful signal and two secondary windings (W2, W3) with the same number of turns and an output transformer (13) ) with a primary winding (W4) and a secondary winding (W5) to pick up the switched-through useful signal, one ends of the secondary windings (W2 or W3) of the input transformer each via the collector-emitter path of one of two complementary transistors (14 or 15) are connected to one end of the primary winding (W4) of the output transformer and the other ends of the secondary windings of the input transformer are each connected to the other end of the primary winding of the through a diode (20 or 21) which is permeable in the forward direction of the associated collector-emitter path Output transformer are connected and wherein the bases of the transistors to the Pick-up points of two voltage dividers (16, 17 or 18, 19) which are connected in parallel to the input terminals (7, 8) for the controlling comparison voltage (FIG. 5). 3. Circuit arrangement according to claim 1, characterized in that the switch is an electronic switch which has an input transformer (22) with a primary winding (W6) acted upon by the received useful signal and two secondary windings (W7, W8) with the same number of turns and an output transformer (23) ) with a central tap having a primary winding (W9, W 1I) and a secondary winding (W10) for picking up the switched-through useful signal, one of the ends of the secondary windings (W7, W8) of the input transformer each via the collector-emitter path one of two Transistors (24, 25) of the same conductivity type are connected together to the center tap of the secondary winding (W12, W14) of an additional control transformer (28) and to the primary voltage tap of the output transformer, with the other ends of the secondary windings (W7, W8) of the input transformer each connected via a diode (26, 27) whose forward direction derj enigen corresponds to the collector-emitter path of the associated transistor (24, 25), are connected to the ends of the primary winding of the output transformer and the bases of the transistors are connected to the outer ends of the secondary winding (W12, W14) of the control transformer whose primary winding (W13) is connected to the input terminals (7, 8) for the controlling comparison voltage. 4. Circuit arrangement according to claim 1, characterized in that the comparison frequency is filtered off the carrier frequency obtained from the received useful signal by means of a filter is.