EP2638783B1 - Interference-free light-emitting means control - Google Patents

Description

The invention relates to an operating device for controlling lighting means and a method for controlling lighting means.

To control bulbs are known in addition to classic direct wired switches a variety of control gear. In such operating devices usually a control signal is transmitted from a switch to a control gear. The operating device receives the signal and performs a corresponding control of the bulb. This can be a switch on or off, but also a dimming process. The control signal is usually either mains voltage or a digital control signal. Frequently, for digital control signals standardized transmission methods, eg. B. DALI used.

Also known is the use of different control signals, eg. B. DALI and mains voltage to a control gear. This allows a great flexibility of the use of the operating device. In particular, with long line lengths, on which the control signal is transmitted, however, results in an unreliable switching behavior, since capacitive or inductive interference can trigger faulty circuits.

This is how the German Offenlegungsschrift shows DE 197 48 007 A1 a conventional operating device with an interface circuit. The disadvantage of this is that a high implementation cost is necessary.

The WO 2009/156952 A1 discloses a lighting device with a receiver and a drive circuit for driving a lamp. The receiver detects two or more consecutive zero crossings of an AC signal for synchronization with a transmitter. The transmitter modulates the AC current as soon as the current level before a zero crossing is small enough. The receiver receives the modulated current, evaluates the data and generates a signal to the drive circuit.

The publication WO 2009/156952 A1 discloses a method and apparatus for controlling electrical appliances and communicating over mains voltage supply lines.

The publication DE 197 48 007 A1 discloses an interface for a lamp operating device.

The invention has for its object to provide an operating device for lighting and a method for operating bulbs, which enable safe switching behavior with low implementation costs, especially for long line lengths.

The object is achieved for the operating device by the features of independent claim 1 and for the method by the features of independent claim 5. Advantageous developments are the subject of the dependent claims.

An inventive operating device for lighting means includes an interface circuit and a drive circuit. The interface circuit is designed to generate an interface signal in response to a control signal. The drive circuit is designed to evaluate the interface signal and to control at least one light-emitting device as a function of the evaluation of the interface signal. The control signal is an AC voltage control signal generated outside the operating device. The interface circuit comprises means for detecting that an upper threshold value is exceeded for only one of two half-waves of the control signal, the interface circuit being adapted for each detection of exceeding the upper threshold value a first signal pulse in the interface signal in the range of the peak value of the positive half cycle of the control signal to create. The interface circuit includes a zero-crossing detection circuit that detects that the negative half-wave of the control signal has exceeded a lower threshold, the zero-crossing detection circuit having a second signal pulse having a lower one than the first signal pulse for each detection of exceeding the lower threshold of the control signal Level generated in the interface signal (21, 31, 41, 51). The drive circuit is configured to detect the presence of the control signal on the basis of the first signal pulse. This enables a simple and at the same time interference-free evaluation of the control signal.

Furthermore, an operating device for lighting means is disclosed, wherein the operating device has an interface circuit and a drive circuit, wherein the interface circuit in response to a control signal generates an interface signal, and wherein the drive circuit drives at least one light emitting device in response to the interface signal, wherein the control signal outside of the operating device wherein the interface circuit detects the exceeding of a lower threshold for at least the majority of the time duration of one of two half-waves of the control signal, and the interface circuit for each detection of exceeding the lower threshold a second signal pulse whose level is lower than that of the first signal pulse in which the interface signal is generated, and in the case of repeated succession of a plurality of such second signal pulses, the presence of a control signal is detected t.

Advantageously, the means for detecting the interface circuit further comprises a peak detection circuit, which can detect the exceeding of the upper threshold and optionally additionally peak values.

As already stated, the zero-crossing detection circuit can detect the exceeding of the lower threshold value and, optionally, additional zero crossings of the control signal. Thus, an additional improvement of the detection of the switching states is possible.

Fig. 1

ein beispielhaftes Beleuchtungssystem;

Fig. 2

ein beispielhaftes Betriebsgerät;

Fig. 3

beispielhafte Signalverläufe in dem beispielhaften Betriebsgerät;

Fig. 4

ein Ausführungsbeispiel des erfindungsgemäßen Betriebsgeräts;

Fig. 5

einen ersten beispielhaften Signalverlauf im Ausführungsbeispiel des erfindungsgemäßen Betriebsgeräts;

Fig. 6

einen zweiten beispielhaften Signalverlauf im Ausführungsbeispiel des erfindungsgemäßen Betriebsgeräts;

Fig. 7

ein dritter beispielhaften Signalverlauf im Ausführungsbeispiel des erfindungsgemäßen Betriebsgeräts;

Fig. 8

ein vierter beispielhaften Signalverlauf im Ausführungsbeispiel des erfindungsgemäßen Betriebsgeräts, und

Fig. 9

ein Ausführungsbeispiel des erfindungsgemäßen Verfahrens.

The invention will be described by way of example with reference to the drawing, in which an advantageous embodiment of the invention is shown. In the drawing show:

Fig. 1

an exemplary lighting system;

Fig. 2

an exemplary operating device;

Fig. 3

exemplary waveforms in the exemplary operating device;

Fig. 4

an embodiment of the operating device according to the invention;

Fig. 5

a first exemplary waveform in the embodiment of the operating device according to the invention;

Fig. 6

a second exemplary signal waveform in the embodiment of the operating device according to the invention;

Fig. 7

a third exemplary signal waveform in the embodiment of the operating device according to the invention;

Fig. 8

a fourth exemplary signal waveform in the embodiment of the operating device according to the invention, and

Fig. 9

an embodiment of the method according to the invention.

First, based on the Fig. 1-3 the problems underlying the present invention, the structure and operation of an exemplary operating device explained. Subsequently, by means of Fig. 4-8 the structure and operation of the operating device according to the invention shown. Finally is determined by Fig. 9 the operation of the method according to the invention explained in more detail. Identical elements have not been repeatedly shown and described in similar figures.

An exemplary lighting system includes a button 4, an operating device 1 and a light source 5. Instead of a button 4, a switch or other input device can be used. The button 4 is connected to the operating device 1. The operating device 1 in turn is connected to the lighting means 5. The light-emitting means 5 may be, for example, a conventional incandescent lamp or a fluorescent lamp or one or more light-emitting diodes, LEDs. Other bulbs can be used here. The operating device 1 consists of an interface circuit 2 and a drive circuit 3. The button 4 is connected to the interface circuit 2 of the operating device 1. The interface circuit 2 and the drive circuit 3 are connected together within the operating device 1. The lighting means 5 is connected to the drive circuit 3 of the operating device 1. The button 4 and the operating device 1 are connected to each other via a line. Furthermore, the operating device 1 can be permanently connected via a supply connection to a mains voltage, from which the drive circuit 3 is fed to supply the lighting means 5.

The button 4 connects, as soon as it is pressed, mains voltage with the interface circuit 2 of the operating device 1. If it is not pressed, the line between the button 4 and the interface circuit 2 is open. Both actuated as well as not actuated switch 4 interference can take place in this line.

The interface circuit 2 evaluates the signals on the line and determines switching operations of the button 4. Based on these switching operations, the interface circuit 2 generates an interface signal and forwards it to the drive circuit 3 on. As a function of the interface signal, the drive circuit controls the lighting means 5. In this case, the interface circuit 2 determines only the switching states of the button 4 and converts them into the interface signal. Only the drive circuit 3 determines from the switching states transmitted to it in the interface signal, the switching operations to be performed. Thus, the drive circuit 3 z. As the operation time, the sequence of operations or the operating rhythm as an indication of the control process to be performed. The interface signal thus provides, for example, a desired value for the drive circuit 3.

Fig. 2 shows an exemplary interface circuit, as shown in the in Fig. 1 could be used. The switched mains voltage Vn is supplied to a rectifier circuit 100 via a resistor R7a of, for example, 20Ω. The rectifier circuit 100 consists of four diodes D1a, D2a, D3a, D4a. These are connected to ground in a conventional bridge rectifier circuit. The rectified signal is supplied to a zero-crossing detection circuit 101. This consists of two transistors Q1a, Q2a and two resistors R1a, R2a. The emitter of the transistor Q1a and the resistor R1a of, for example, 332Ω are directly connected to the rectified signal. The resistor R1a is further connected to the base of the transistor Q1a and the emitter of the transistor Q2a connected. The collector of the transistor Q1a in turn is connected to the base of the transistor Q2a and the resistor R2a of, for example, 150 KΩ. The collector of the transistor Q2a is further connected to the second side of the resistor R2a. At this point, the signal exits the zero-crossing detection circuit. The signal is fed via an additional diode Z3a to an optocoupler Q4a. This is connected via a further resistor R3a, for example, 10kΩ with a supply voltage V2, for example, 15V. The interface signal can be taken from the secondary side of the opto-coupler Q4a.

The zero-crossing detection circuit 101 generates a pulse every zero crossing of the applied signal. Depending on the steepness of the voltage passage through the zero point results in a different width pulse. Such a pulse typically has a duration of 100 microseconds. Such a pulse is well transferable by the optocoupler Q4a.

Fig. 3 shows an exemplary waveform in an interface circuit, such. In Fig. 2 shown. A control signal 10 has a frequency of 50 Hz and thus a period of 20 ms. The interface signal 11 has only individual pulses 12 at the zero crossings of the control signal 10. Shown here is the trouble-free case. The interface signal on the secondary side of the optocoupler Q4a can now be evaluated with regard to the detected zero crossings. On the basis of the recognized sequence of zero crossings can thus be concluded on the operation of the button, as for a certain period (eg in the range of 400 to 1000 milliseconds) a mains voltage was supplied to the interface circuit.

Disturbances can produce steeper signal paths in the areas of the zero crossings of the control signal. The pulse duration decreases drastically in this case. This can go so far that the optocoupler Q4a out Fig. 2 the signal can no longer be transmitted properly.

Threshold values of -6.5V to 6.5V amplitude of the mains voltage are typically provided to detect the zero crossings. These threshold values should not be changed, as the interface should advantageously also be used for digital DALI signals, and the DALI digital LOW signal should be below 6.5 V. The problem of the invention thus exists in particular at interfaces of operating devices for lamps, which are to process both digital signals, as well as AC signals.

It can thus happen that zero crossings are not recognized in such operating devices, resulting in a faulty control, which affects the more drastic when multiple devices are addressed starting from the same button operation, which then due to different disturbances on their lines different controls of devices connected to the same button or switch. A reduction of this problem can be achieved if, in addition to detecting the zero crossings in particular, a detection of the peak value ranges of the mains voltage takes place. Thus, for example, a relatively long peak value in each case in the range of the maximum of the mains voltage in addition to the relatively short pulses can be generated in the area of the zero crossings in the interface signal, which could improve control safety.

However, a problem with this is that different long pulses in the range of the peak values of the mains voltage are generated with different sized network amplitudes. In addition, with the line open, i. H. capacitively coupled with a button that is not pressed or a switched switch, which can be such that the resulting signal is no longer distinguishable from that when pressed switch or button. In particular with large cable lengths, this can lead to faulty switching when the cable is open.

Fig. 4 shows an embodiment of the operating device according to the invention for lighting means. As in the control gear Fig. 2 a switched mains voltage Vn is supplied to a rectifier circuit 200 via a network resistor R _network of, for example, 20Ω. The rectifier circuit 200 largely corresponds to the rectifier circuit 100 Fig. 2 , Four diodes D1 - D4 are connected in a common bridge rectifier circuit to ground. The rectified control signal is transmitted from the rectifier circuit 200 to a zero-crossing detection circuit 201. This substantially corresponds to the zero-crossing detection circuit 101 Fig. 2 , A first resistor R1 of, for example, 332Ω and the emitter of a first transistor Q1 are supplied with the rectified signal. The second side of resistor R1 is connected to the base of this first transistor Q1. The collector of the first transistor Q1 is connected to the base of a second transistor Q2 connected. Furthermore, the base of the first transistor Q1 is connected to the emitter of the second transistor Q2. Moreover, the base of the second transistor Q2 is further connected to the first side of a second resistor R2 of, for example, 150kΩ. This resistor R2 is connected to ground. The output of this zero-crossing detection circuit is applied to the collector of the transistor Q2 and is supplied from this Zener diode Z2.

The control signal Vn is further supplied to a peak detection circuit 202 via the _network resistor R _Netz . It first passes through a Zener diode Z1. Since the Zener diode Z1 forms a kind of threshold value switch with its predetermined breakdown voltage and only turns on when a predefined threshold voltage is exceeded, only the peak values above a predetermined upper threshold value of one of the two half-cycles of the alternating voltage signal pass through the Zener diode Z1. Signal components which lie below the breakdown voltage of the Zener diode Z1, ie below the predetermined upper threshold value, are not forwarded. This includes, in particular, the second half-wave of the alternating voltage signal Vn. Instead of the Zener diode Z1, it is also possible to use a resistance divider which is dimensioned to the threshold voltage of the transistor Q3.

By way of an ohmic resistance R4 of, for example, 100 kΩ, the resulting signal is supplied to the base of a transistor Q3. The emitter transistor Q3 is connected via an ohmic resistor R5, for example, 10kΩ to the Base of transistor Q3 and continue to ground. This transistor Q3 provides a uniform rectangular pulse shape. The output signal of the peak detection circuit 202 is applied to the collector of the transistor Q3 and is supplied from this also the Zener diode Z2.

The signal applied to the Zener diode Z2 is as well as in Fig. 2 via an optocoupler Q4, which is supplied via an ohmic resistor R3, for example, 7.5 kΩ with a supply voltage V1 of 3.3V, transmitted to the drive circuit. The actual transmission of the interface signal is effected by the secondary part of the optocoupler Q4.

A resulting signal of the interface circuit Fig. 4 can in Fig. 5 be seen. So shows Fig. 5 the control signal 10 and at the same time the interface signal 21, which corresponds to the output signal of the optocoupler. For clarity, different scales were used for the two signals. The interface signal 21 now has both pulses 23 at the zero crossings of the control signal 10, as well as wide pulses 22 in the range of the peak values of the positive half cycle of the control signal 10 (ie when the upper threshold value is exceeded). Connecting the peak detection circuit 202 to the inverted input of the rectifier circuit 200 would result in a wide pulse 22 at the level of the negative half wave of the AC signal 10.
The pulses 23 at the zero crossings of the control signal 10 result because the zero-crossing detection circuit 201 in conjunction with the Zener diode Z2 only transmits a current when the voltage of the control signal 10 has exceeded some potential (both positive and negative). As long as the voltage of the control signal 10 is so small that the zero-crossing detection circuit 201 in connection with the Zener diode Z2 still leads to no current flow in the primary side of the opto-coupler Q4, since the threshold voltage of the Zener diode Z2 is not reached, is the optocoupler Q4 secondary side not durchgesteuert and thus is on the secondary side, an interface signal 21 at high level (23), which is interpreted as logic "1".

When the voltage of the control signal 10 has exceeded some potential (hereinafter referred to as the lower threshold) (due to the rectifier D1-D4 in both the positive and negative directions), the current flowing through the zero-crossing detection circuit 201 is sufficient to drive through the Zener diode Z2 and a current flows through the primary side of the optocoupler Q4, whereby the optocoupler Q4 on the secondary side drives through. Thus, on the secondary side, there is an interface signal 21 with a low level 24, which is interpreted as a logical "0". Thus, when the button is depressed and the voltage of the control signal 10 is not very close to the zero crossing, a current and the opto-coupler will flow through the primary side of the opto-coupler Q4 due to the activation of the zero-crossing detection circuit 201 in conjunction with the zener diode Z2 Q4 controls on the secondary side. Thus, on the secondary side, there is an interface signal 21 with a low level 24, which is interpreted as a logical "0".

When a mains voltage is applied due to the pressed button, an interface signal 21 with a low level 24 is therefore present during the negative half-wave for a large part of this half-cycle, which can be interpreted as logic "0". Preferably, a concern of a network voltage is detected by the fact that for the interface signal 21 regularly for the duration of almost a network half-wave, ie at least 9 ms, a low-level signal 24 is applied. Thus, a concern of a mains voltage, so the operation of the button, by evaluating a longer phase of the concern of a signal with a low level 24 (ie, the reception of a logical "0") take place.

If the button is not pressed, ie an open line is present, capacitive interference signals can be coupled in with a correspondingly long line. However, this injected mains voltage will never reach the switching threshold of the Zener diode Z1, so that this branch never becomes active, i. H. the transistor Q3 is never turned on, which would pull the node in front of the Zener diode Z2 to a voltage of 0V.

Rather, the bipolar coupled noise voltage will only make a contribution in the branch to the rectifier with the diodes D1 - D4, provided that the injected voltage at least sufficient that this voltage exceeds the lower threshold and thus the zero crossing detection circuit 201 in conjunction with the Zener diode Z2 lets a current through.

Each rectified half-wave of the control signal Vn thus generates from the exceeding of the lower threshold, a certain current flow by means of Transistors Q1 and Q2 at the input of optocoupler Q4. A current flow through the primary side of the optocoupler Q4 is interpreted on the output side as logic "0" (analogous to the DALI standard, which leads to a voltage of more than 0 V in the high state). However, the duration of such a signal with logic "0" is only in the range below 5 ms. An interference signal when the switch is not pressed can thus lead, when using a detection based on the zero crossings according to the prior art, that current can flow in each half-wave, which can then be interpreted on the output side as a zero crossing.

In Fig. 6 is an exemplary waveform in the operating device according to the invention after Fig. 4 shown with open line and a capacitive fault. The capacitively coupled mains voltage 31 has a phase offset of 90 ° with respect to the control signal 10. Since the button is not pressed, the interface circuit detects no zero crossings of the actual mains voltage 10. Instead, the zero crossings of the capacitively coupled signal 31 in the interface signal 30, which corresponds to the output signal of the optocoupler detected. This results in pulses 32, 33 in the interface signal. However, since there are no longer pulses in the interface signal which correspond to the exceeding of the upper threshold values (peak values) of one half-wave respectively, and / or no sustained phase with low level, the subsequent drive circuit accepts the signal not valid signal and thus not as an indication the operation of the switch or button.

If, however, a real mains voltage is applied by pressing the switch or button as a control signal, the Threshold of the Zener diode Z1 (upper threshold) is exceeded and the transistor Q3 is turned on, whereby the point in front of the Zener diode Z2 is pulled to a voltage of 0V, which in turn is interpreted in the interface signal 30 on the output side as logic "1". In the half-wave of the reverse polarity of the upper circuit branch is not used, ie the transistor Q3 is never turned on. On the contrary, due to the zero-crossing detection circuit 201 in combination with the Zener diode Z2, a current flow through the transistors Q1, Q2 will always result for this majority half-wave, which on the output side is interpreted as logic "0".

Thus, only when a true mains voltage is applied and not when a noise voltage is injected is there a difference between the halfwaves of different polarities. Only in the case of a half-wave will logic "1" be present due to the activation of the upper circuit branch on the output side. In contrast, regardless of the polarity of the half-waves, depending on the amplitude of the coupled-in interference voltage, a current will always flow for a significantly shorter period of time than the duration of a line half-cycle in the case of the injected interference voltage. H. output always logical "0" abut when current flows.

A logical "0" from a time duration above a threshold of e.g. B. at least 9 ms during a first half-wave can therefore only be generated when a deliberate mains voltage is applied. If the zero crossings are filtered out, the pulses with a level of logic "0", ie with a low level, last at least 10 ms. In addition, only with conscious application of a Mains voltage of the upper circuit branch can be activated with the Zener diode Z1. Primary side so flows at a noise voltage in each half-wave for a much shorter period than the duration of a half-wave power. In a deliberately generated by button operation mains voltage signal flows in at least every other half-wave for almost the entire duration of this half-wave in the lower branch 201, a current and every other half-wave (certain period) in which the network amplitude is above the threshold voltage of the Zener diode Z1 flows no current in the optocoupler. Therefore, to discriminate the switch operation, it is necessary to determine the state that current does not flow to the optocoupler Q4 during certain sections of every other half-wave, and / or that current always flows into the optocoupler in the other half-wave, as long as certain threshold values of z. B. -6.5V and + 6.5V are exceeded.

Thus, it is also possible that the interface circuit 2 detects exceeding the lower threshold for at least the majority of the duration of one of two half-waves of the control signal 10, and that the interface circuit 2 for each detection of exceeding the lower threshold, a low level signal pulse 24 in the Interface signal 21 is generated, and upon repeated succession of such low-level signal pulses 24 detects the presence of a control signal 10.

In Fig. 7 Once again an exemplary waveform in the operating device according to the invention after Fig. 4 shown here with an open line of 350m length. The Control signal 10 is thus not applied to the input of the interface circuit. Instead, only an injected signal 41 is present. The pulses 42, 43 of the interface signal 40 become shorter and shorter as the line becomes longer. However, it is still possible to distinguish between intentionally applied line voltage and coupled signals.

In Fig. 8 By contrast, it is assumed that an open line of at least 550m in length. The peak values 54 of the coupled-in signal 51 here reach a height such that the breakdown voltage of the Zener diode Z1 is off Fig. 4 is exceeded. Thus, as with the presence of a network signal, 10 pulses 55 are generated in the region of one half-wave of the injected signal 51. In addition, pulses 52, 53 are generated in the region of the zero crossings of the injected signal 51. A distinction between a coupled-in signal 51 and an applied network signal 10 is no longer possible. In particular, the phase shift between the network signal 10 and the injected signal 51 results in an asynchronism of various connected devices and faulty circuits. However, cable lengths of more than 500m are unusual for a luminaire or lighting installation and therefore this case need not be considered further.

Fig. 9 shows an embodiment of the method according to the invention. In a first step 300, the peak values of each of two half-waves of a control signal are detected. The peak values are all values above a threshold voltage. In a second step 301, the control signal is rectified. The resulting rectified control signal is from successive half-waves of identical sign.

In an optional third step 302, zero crossings of the control signal are detected by determining zero points of the rectified control signal. In an alternative variant, the zero crossings of the control signal can also be easily filtered out (for example by filtering out pulse durations of less than 150 μs). In a fourth step 303, the determined peak values (exceeding of the upper threshold value) and the activation of the lower branch 202 and optionally the determined zero crossings are included in a common interface signal. In a fifth step 304, the interface signal is evaluated with regard to logic states and the switching processes intended thereby. In a sixth step 305, the lighting means is driven in accordance with the control specifications determined in the preceding step.

The invention is not limited to the illustrated embodiment. Various lamps can be controlled according to the invention. The use of deviating input devices, such. As touch-sensitive displays, etc. is conceivable.

Claims (8)

1. An operating device (1) for an illuminant (5),
   wherein the operating device (1) has

   - an interface circuit (2) for generating an interface signal (21, 31, 41, 51) depending on a control signal (Vn, 10) generated outside of the operating device (1), which is designed in the form of a supply voltage control signal, and

   - a drive circuit (3) for evaluating the interface signal (21, 31, 41, 51) and for the control at least of one illuminant (5) depending on the evaluation of the interface signal (21,31,41,51),

   - wherein the interface circuit (2) comprises means for detecting an overshooting of an upper threshold value of the control signal (Vn, 10),

   - wherein the interface circuit (2) is designed to generate a first signal pulse (22, 55) for each detection of the overshooting of the upper threshold value,

   - wherein the interface circuit (2) comprises a zero-crossing detection circuit (201),

   - wherein the zero-crossing detection circuit (201) identifies an overshooting of a lower threshold value of the negative half-cycle of the control signal (Vn, 10), and

   - wherein for each detection of the overshooting of the lower threshold value of the control signal (Vn, 10) the zero-crossing detection circuit (201) generates a second signal pulse having a low level (24) compared to the first signal pulse (22, 55) in the interface signal (21, 31, 41, 51),

   characterized in

   - that the means for the detection is designed to detect an overshooting of the upper threshold value only in one of the two half-cycles of the control signal (Vn, 10);

   - that the interface circuit (2) is designed to generate the first signal pulse (22, 55) in the interface signal (21, 31, 41, 51) in the range of the peak value of the positive half-cycle of the control signal (Vn, 10); and

   - that the drive circuit (3) is arranged to identify the presence of the control signal (Vn, 10) on the basis of the first signal pulse (22, 55).
2. An operating device (1) according to Claim 1,

   - wherein the first signal pulse (22, 55) has a length of at least 1 ms, preferably of at least 3 ms, and

   - wherein the first signal pulse (22, 55) has a length of at most 10 ms, preferably a length of at most 8 ms,

   - wherein the supply voltage control signal has a frequency of 50 Hz.
3. An operating device (1) according to Claim 1,

   - wherein the second signal pulse (24) has a length of at least 9 ms, preferably of 9.5 ms,

   - wherein the supply voltage control signal has a frequency of 50 Hz.
4. An operating device (1) according to any one of Claims 1 to 3,

   - wherein the interface circuit (2) comprises a rectifier circuit (200), and

   - wherein the rectifier circuit (200) is arranged to rectify the control signal (Vn, 10).
5. A method for operating illuminants (5),

   - wherein depending on a control signal (Vn, 10) generated outside of an operating device (1), which control signal is designed in the form of a supply voltage control signal, an interface signal (21, 31, 41, 51) is generated, and

   - wherein the interface signal (21, 31, 41, 51) is evaluated and an illuminant (5) is actuated depending on the evaluation of the interface signal (21, 31, 41, 51),

   - wherein an overshooting of an upper threshold value of the control signal (Vn, 10) is detected,

   - wherein for each detection of the overshooting of the upper threshold value a first signal pulse (22, 55) is generated, and

   - wherein the zero-crossings of the control signal (Vn, 10) are identified,

   - wherein an overshooting of a lower threshold of the negative half-cycle is detected, and

   - wherein for each detection of the overshooting of the lower threshold value a second signal pulse (24) is generated having a low level (24) compared to the first signal pulse (22, 55) in the interface signal (21, 31, 41, 51),

   characterized in,

   - that an overshooting of the upper threshold value is detected only in one of the two half-cycles of the control signal (Vn, 10);

   - that the first signal pulse (22, 55) in the interface signal (21, 31, 41, 51) is generated in the range of the peak value of the positive half-cycle of the control signal (Vn, 10); and

   - that the drive circuit (3) identifies the presence of the control signal (Vn, 10) on the basis of the first signal pulse (22, 55).
6. A method according to Claim 5,

   - wherein the first signal pulse (22, 55) has a length of at least 1 ms, preferably of at least 3 ms, and

   - wherein the first signal pulse (22, 55) has a length of at most 10 ms, preferably of at most 8 ms,

   - wherein the supply voltage control signal has a frequency of 50 Hz.
7. A method according to Claim 5,

   - wherein the second signal pulse (24) has a length of at least 9 ms, preferably of 9.5 ms,

   - wherein the supply voltage control signal has a frequency of 50 Hz.
8. A method according to any one of Claims 5 to 7,

   - wherein the control signal (Vn, 10) is rectified.

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