CH649659A5 - Method and circuit arrangement for protection against ripple-control receivers switching incorrectly as a result of interference pulses - Google Patents

Description

The invention relates to a method for protecting against false switching of ripple control receivers caused by interference pulses, which respond to a preselection command and a double command exclusively assigned to it for the on and off command.

The invention further relates to a circuit arrangement for carrying out the method in a ripple control receiver, which has an input part, a downstream decoder and a logic stage which on the input side is directly connected to the decoder on the one hand, and on the other hand to the decoder via a preset memory, and at least one output switching element the ripple control receiver can be actuated by the link level.

In order to prevent faulty switching due to interference impulses, ripple control systems have so far had so-called “monitored” area codes or complicated area code addresses, such as a combination of n bits selected from eight possible bits. Without a doubt, this can significantly increase the security against incorrect switching.

If, however, the preselection is recognized in the ripple control receiver during a control pulse sequence, the double command for the on and off command is protected as little in the further course of the control pulse sequence as a double command without a preselection. The advantage of the previous method with preselection is only that a double command with preselection cannot be addressed when every control pulse sequence is received.

The object of the invention is to improve a method of the type described in the introduction in such a way that, after recognition of the area code in the receiver, the subsequent double command and the area code exclusively assigned to the area code are equally protected against incorrect switching.

This object is achieved with the method according to the invention in that the on and off command pulses of the double command are monitored in such a way that a switching action is only released if only one of these command pulses is present during a control pulse sequence.

It is advantageous if the first command pulse of the double command or a first interference pulse pending at this point in time is stored at least until the assigned second command pulse or a second interference pulse is received, and that the storage is carried out by a second command pulse or a second interference pulse pending at this point in time is deleted.

It is advantageous if the output switching element is actuated by a call command from the decoder only when the memory has not been deleted.

The call command can be issued at the end of the term of an internal time step.

A preferred circuit arrangement for performing the method is that a logic stage is connected between the logic stage and the output switching element, which is also connected to a call output of the decoder and which only forwards a switching pulse to the output switching element if within a pulse transmission up to the time of Pending a call command in the logic level, only an output pulse of the logic level was registered.

An advantageous embodiment of the circuit arrangement is that the logic stage has a counter with the capacity of 1 bit and an AND gate, the input of the logic stage connected to the output of the logic stage being connected to the input of the counter, whose output signal at one input of the AND gate is present, the second input of which forms the call input of the logic stage connected to the call output of the decoder, and the output of the logic stage is connected to the output of the AND gate.

The invention is explained in more detail below using an exemplary embodiment in FIGS. 1 to 7.

1 shows a pulse template of the ripple control receiver,

2 shows a pulse transmission which is recognized by the ripple control receiver,

3 shows a pulse transmission, which is also recognized by the ripple control receiver,

4 shows a pulse transmission with an interference pulse,

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5 shows a basic circuit diagram of the ripple control receiver,

6 shows a pulse transmission disturbed by long interference pulses,

7 shows the structure of logic stage 14.

Fig. 1 shows a pulse template of the ripple control receiver, which carries out the programming of the receiver and thus the selection of the pulse transmission or control pulse train intended for the ripple control receiver from the totality of the pulse transmissions or control pulse trains transmitted via the electrical supply network. Reference number 1 'denotes the pulse window for the start pulse. For the sake of simplicity, only the two pulse windows 2 'and 3' (monitored preselection) are provided for the preselection. It is then monitored that

that a preselection pulse occurs in the incoming pulse transmission or control pulse train in the pulse window 2 ', but that no pulse of the control pulse train falls in the pulse window 3'. The pulse window 2 'and 3' for the preselection pulses are at a predetermined time interval from the pulse window 1 'for the start pulse, so that only one pulse transmission or control pulse sequence provided for the ripple control receiver concerned is received by this ripple control receiver as intended for it. The pulse windows 5 'and 6' of the double command 4 for the on and off command are also at a certain time interval from the pulse window Y for the start pulse, e.g. the impulse window 5 'is assigned the on command and the impulse window 6' is the off command. Both the position of the two pulse windows 5 'and 6' to one another and the position between the pulse window 3 'and the end of the evaluation can differ depending on the control pulse sequence used.

FIG. 2 shows a pulse transmission or control pulse sequence with a control pulse sequence recognized by the ripple control receiver described, as is defined by the pulse template of the ripple control receiver in FIG. 1. If the start pulse 1 is followed by the pre-selection pulse 2, which represents the pre-selection for the double command 4, and finally follows a pulse 5 in the pulse window 5 'of FIG. 1, a switching action is triggered in which, for example, a relay serving as output switching element 13 is switched on becomes.

Fig. 3 shows a pulse broadcast, which is also recognized by the ripple control receiver. In contrast to the pulse sequence according to FIG. 2, a pulse 6 occurs here, which falls within the pulse window 6 'of the receiver-side pulse template assigned to the switch-off command, and which results in the output switching element 13 being switched off.

The pulse window 3 'of the pulse template of the ripple control receiver may not register a pulse or a pulse-like disturbance as part of the pulse transmission according to FIGS. 2 and 3, since otherwise the preselection is canceled and the switching operation of the output switching element is omitted.

5 shows the basic circuit diagram of a ripple control receiver, the input part 7 of which is supplied to the mains voltage via lines 8. In the input part 7, the audio frequency signals superimposed on the mains voltage and representing the pulse transmission are screened out and fed to a decoder 9. When the preselection is recognized - the pulse corresponding to the pulse window 2 'of the pulse template of the ripple control receiver must be present, the pulse associated with the pulse window 3 of the pulse transmission must not be present - a preselection memory 10 is set, which gives a signal to a logic stage 11. The linkage stage 11 is also connected via a line 12. Off command pulse 5 or 6 of the double command 4 supplied. In the conventional method, when the corresponding control pulse arrives via the line

12, the link stage 11 immediately issues a command to the output switching element 13. According to the invention, however, in order to protect the double command 4 according to FIG. 1 against interference pulses, a logic stage 14 is switched on between the logic stage 11 and the output switching element 13, which monitors the on and off command pulses of the logic stage 11 and only then to the output switching element

13 switches through when only one pulse is received and a corresponding signal representing the call command comes from the decoder 9 via a call line 15. The call command can be derived from the pulse transmission. The call command can also be issued at the end of the runtime of an internal time step, this time step being started when a pulse train is received, for example by the start pulse 1. The end of the runtime of the internal time step must necessarily be later than the double command.

The mode of operation of this circuit is explained with reference to FIGS. 4 and 6. FIG. 4 shows a control pulse sequence which initially corresponds to the control pulse sequence shown in FIG. 2. With the conventional construction of a ripple control receiver, this would mean that when the pulses 2 and 5 arrive, the output switching element 13 is switched on. Would an interference pulse 16 now occur, for example, which temporally enters the switch-off pulse window 6 '

falls, so - without the invention - the switching action initiated by pulse 5 would be immediately reversed, since such a pulse 16 can no longer be blocked by the preselection. For this reason, the logic stage 14 is provided according to the invention, which only forwards a command to the output switching element 13 if only a single command for the double command 4 has been received until the call.

FIG. 6 shows a pulse sequence disturbed by long interference pulses 17 and 18. If an interference pulse 17 occurs, the preselection would be blocked, as is known, because the interference pulse 17 falls into the pulse window 3 ', which must remain unoccupied if the pulse sequence is correct. An interference pulse 18, which coincides in time with the double command 4, would block the logic stage 14, even if a correct pre-selection pulse 2 was received and the pre-selection was thus recognized, because the double-command 4 has both the on and off pulse 5 and 6 be received.

The pre-selection pulse 2 may only be sent if either the switch-on pulse 5 or the switch-off pulse 6 is sent, since at least one correct pulse is expected in the method. If a correct preselection pulse 2 arrives without an on or off command pulse 5 or 6 occurring, an interference pulse falling into the pulse window 5 'or 6' would simulate a correct pulse transmission. In this respect, the area code can only be assigned to double command 4.

FIG. 7 shows the circuitry structure of the logic stage 14. The logic stage 14 comprises a counter 19 with a capacity of 1 bit. The input of the counter 19 is connected to the input of the logic stage 14, so that the output signal of the logic stage 11 is present here. At the output of the counter 19, the value 1 is thus within a pulse transmission when a pulse coming from the combination stage is received, and the value 0 when two pulses are received. Furthermore, the logic stage 14 has an AND gate 20 with two inputs. The output signal of the counter 19 is fed to one input of the AND gate 20. A call command, which is issued, for example, at the end of a control pulse sequence by the decoder, can be fed via the second input of the AND gate 20. The output of the AND gate 20 is with the output switching element 13

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connected. If the output of the counter 19 has the value 1 - this can only be the case if one and only one on or off command is contained in the received control pulse sequence - and a call command is received at the second input of the AND gate 20 , the intended switching action takes place by controlling the output switching element 13 via the AND gate, since in this case the UN D condition is fulfilled. Assigns the pulse train for both pulse positions 5 and

6 of the double command, for example due to a fault, in addition to the proper on or off command pulse, a further pulse then the counter 19 receives two pulses coming from the logic stage, so that 5 its output signal has the value 0. In this case, the AND condition of the AND gate 20 is no longer met, so that no switching action is initiated on the output switching element.

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Claims (6)

649 659 PATENT CLAIMS 1.Procedure for protection against false switching of ripple control receivers caused by interference pulses, which respond to a preselection command and an exclusively assigned double command for the on and off command, characterized in that the on and off command pulses (5 or 6) of the double command ( 4) are monitored in such a way that a switching action is only released if only one of these command pulses (5 or 6) is present during a control pulse sequence. 2. The method according to claim 1, characterized in that the first command pulse (5) of the double command (4) or a pending first interference pulse (18) at least until the possible arrival of the assigned second command pulse (6) or a second interference pulse ( 16) is stored and that the storage is deleted by a second command pulse (6) or a second disturbance pulse (16) which is pending at this point in time. 3. The method according to claim 2, characterized in that the output switching element (13) is actuated only when the storage has not been deleted by a call command from the decoder (9). 4. The method according to claim 3, characterized in that the call command is issued at the end of the term of an internal time step. 5. Circuit arrangement for carrying out the method according to claim 4, wherein a ripple control receiver, which has an input part, a downstream decoder and a logic stage, which is on the input side directly connected to the decoder, on the other hand, via an area code memory with the decoder, and at least one Output switching element of the ripple control receiver can be actuated by the logic stage, characterized in that a logic stage (14) is connected between the logic stage (11) and the output switching element (13), which is also connected to a call output of the decoder (9) and only then one Passes switching pulse to the output switching element (13) if only one output pulse of the logic stage (11) has been registered within a pulse transmission up to the time a pending command is present in the logic stage (14). 6. Circuit arrangement according to claim 5, characterized in that the logic stage (14) has a counter (19) with the capacity of 1 bit and an AND gate (20), the input connected to the output of the logic stage (11) Logic stage (14) is connected to the input of the counter (19), the output signal of which is present at an input of the AND gate (20), the second input of which forms the call input of the logic stage (14) connected to the call output of the decoder, and the Output of the logic stage (14) is connected to the output of the AND gate (20).