EP2783551B1 - Connection detection of led units - Google Patents

Description

The invention relates to a connection detection for lamps according to the preamble of patent claim 1, a method for connection detection according to the preamble of claim 2 and a lighting system with at least one lamp according to the preamble of claim 10.

Technical area

Such methods are used to control operating devices for lighting and are used in lighting systems to turn on and off bulbs by means of a central control unit and adjust the brightness. Usually, the bulbs are driven by operating devices. The operating devices are grouped together and can be controlled by one or several central control units. The term bulbs refers to both gas discharge lamps and halogen lamps or light emitting diodes (LED). Such a light source can be arranged individually or together with other light sources in a luminaire, which may also contain the operating device.

State of the art

According to the prior art operating devices are addressed by the fact that the connection between the lamp and the operating device is interrupted. This interruption is detected by the operating device and this operating device accepts the current from the central control unit assigning address. This type of addressing requires a lot of time and effort, because during the installation of the entire lighting system each lamp must be separated.

Although there are already methods for automatic address assignment, for example by random number, but in large lighting systems require a lot of time and it can lead to many duplicate addresses. The avoidance of these double addressing requires a high time and computational effort according to the known prior art. The publication DE 10 2008 061 089 A1 discloses a method of bisecting an address to a bus-enabled LED driver.

Presentation of the invention

The object of the invention is achieved for a method according to the invention by the characterizing features of claims 1 and for a generic device according to the invention by the characterizing features of claim 7. Particularly advantageous embodiments of the invention are described in the subclaims.

In this way it is possible to provide an addressing method for a luminous means which can be carried out in a simple and fast manner.

Description of the preferred embodiments

• Fig. 1 zeigt eine Ausgestaltung einer LED Beleuchtungssystems
• Fig. 2. zeigt einen Teil einer Ausgestaltung einer LED Beleuchtungssystems
• Fig. 3 zeigt einen Teil einer Ausgestaltung einer LED Beleuchtungssystems
• Fig. 4 zeigt eine Ausgestaltung der Signalübertragung im Normalbetrieb
• Fig. 5 zeigt eine Ausgestaltung des Ablaufs einer erfindungsgemäßen Adressierung

The invention will be explained in more detail with reference to the accompanying drawings. Show it:

• Fig. 1 shows an embodiment of an LED lighting system
• Fig. 2 , shows a part of an embodiment of an LED lighting system
• Fig. 3 shows a part of an embodiment of an LED lighting system
• Fig. 4 shows an embodiment of the signal transmission in normal operation
• Fig. 5 shows an embodiment of the flow of an inventive addressing

The invention will be explained with reference to an embodiment of an LED lighting system.

The invention will be explained with reference to an embodiment of an LED lighting system BA with a central control unit 12 and the operating devices 1, 1 ', 1 ", 1' ^x , 1 ' ^y .

The present invention can be applied to all types of lighting apparatus. The use of very different lamps is possible, it can be used in particular inorganic or organic light-emitting diodes.

The operating devices 1, 1 ', 1'',1' ^x , 1 ' ^y , and the central control unit 12 are part of an LED lighting system BA.

The bus line 6 is designed as a two-wire data line, which transmits a digital signal with a low DC voltage as the control command.

For example, a data transmission according to a digital communication is transmitted via the bus line 6.

It should be noted that the data transmission of the control commands via the bus line 6 does not have to be wired, but it can be transmitted for example wirelessly via a radio link or via a power line communication (PLC) via the supply network 5. Standardized transmission methods for wired data transmission also exist in each case for the transmission variants mentioned, wherein according to the method according to the invention a modified data transmission can take place via the same bus line 6.

The central control unit 12 can optionally control one or several operating devices 1 of lighting devices via a bus line 6, wherein they can receive and also send digital control commands.

The central control unit 12 can control a plurality of independent operating devices 1 and at the same time supply them with a supply voltage (the central control unit 12 assumes the function of a power supply for the operating devices 1). The independent operating devices 1 can be distinguished from each other by different addresses. The supply by the central control unit 12 can be effected for example by a stabilized DC voltage (for example 48V). Preferably, the central control unit 12 also includes a potential separation such as. A transformer and preferably also an active power factor correction circuit. The central control unit 12 can be connected to a mains voltage (for example 230 V AC).

It is possible to connect individual operating devices to the central control unit 12 or to disconnect them during operation of the LED lighting system (as with current supply by the central control unit 12).

Furthermore, the central control unit 12 can also be directly configured and controlled by a user via directly connected buttons or switches, through an interface to a programming device, through a touchscreen or other adjustment options. Due to the direct control option, the user can also specify control commands, such as brightness values.

Within the LED illumination system BA with at least one luminous means, the luminous means, which are supplied and controlled by at least one operating device 1, 1 ', 1 ", 1' ^x , 1 ' ^y depending on commands of a central control unit 12, can have an address Assignment of the operating devices 1, 1 ', 1'',1' ^x , 1 ' ^y to be given address A (also called short address A) can be due to the temporally determined load behavior of the operating devices (1, 1', 1 "..) , Already at delivery of the operating devices 1, 1 ', 1 ", 1' ^y a preset address L ^x, 1 1 ^'y can in the operation device 1, 1'',1' ^x 1 ', respectively to be stored. However, this preset address L (also called long address L) may have been allocated for a plurality of operating devices 1, 1 ', 1 ", 1' ^x , 1 ' ^y or may also be unsuitable for communication on the bus line 6 trouble-free and user-friendly control of the LED lighting system BA, it is necessary that each operating device 1, 1 ', 1'',1' ^x , 1 ' ^y or each light source has a unique, only once assigned address.

The possible procedure of an addressing is based on the FIGS. 2 to 5 described.

• Versorgen der Betriebsgeräte (1, 1', 1" ..) mit Spannung durch die zentrale Steuereinheit (12),
• Aussenden eines Taktsignals (CLK) auf einem internen Bus, über den die Betriebsgeräte (1, 1' , 1"..) mittels Befehlen einer zentralen Steuereinheit (12) angesteuert werden, wobei die Betriebsgeräte das Taktsignal auf einem Rück-Kanal des internen Busses zurücksenden,
• Zuschalten eines weiteren Betriebsgerätes (1a) an die zentrale Steuereinheit (12),
• Aussenden eines Fehler-Signals auf dem Rück-Kanal (BCK) des internen Busses durch das zugeschaltete Betriebsgerät (la), wobei dieses Fehler-Signal nicht synchron zu dem Taktsignal (CLK) gesendet wird,
• Erkennen des Fehler-Signals durch die zentrale Steuereinheit (12),
• Zuweisen von Adressen (A) für das zugeschaltete Betriebsgerät (1a) durch die zentrale Steuereinheit (12).

According to the invention, a connection detection for an LED lighting system (BA) is proposed, wherein LED (8) as lighting means by at least one operating device (1, 1 ', 1 "..) are controlled depending on commands from a central control unit (12) marked through the following steps:

• Supplying the operating devices (1, 1 ', 1 "..) with voltage by the central control unit (12),
• Transmitting a clock signal (CLK) on an internal bus via which the operating devices (1, 1 ', 1 "..) are controlled by means of commands from a central control unit (12), the operating devices transmitting the clock signal on a back channel of the internal bus return,
• Connecting a further operating device (1a) to the central control unit (12),
• Transmitting an error signal on the back channel (BCK) of the internal bus by the connected operating device (la), this error signal is not sent in synchronism with the clock signal (CLK),
• Recognition of the error signal by the central control unit (12),
• Assigning addresses (A) for the connected operating device (1a) by the central control unit (12).

As in FIG. 1b can be seen, the modular circuit concept according to the invention on a first module 12, which is preferably supplied with the input voltage 9, in particular AC line voltage. This input voltage 9 is supplied to a first submodule A, which typically carries out a rectification of the AC voltage supplied as input voltage 9, in which case the rectified AC voltage is fed to an actively clocked PFC (Power Factor Correction) circuit of the submodule A, if present.

The output voltage of the first submodule A is a DC voltage, hereinafter referred to as 'bus voltage Vbus', which is supplied to a second submodule B of the first module 12. The second sub-module B has essentially the function of a galvanic isolation (insulation) and can, for example, have as a galvanic separating element a transformer. In addition, the second sub-module B serves to provide a stabilized DC voltage, the DC supply voltage 5.

The submodule G denotes a control unit of the module 12, which may be implemented in particular as an integrated circuit, such as ASIC or microprocessor or hybrid thereof. As schematically in FIG. 1 shown, controls this control unit G active switching elements of the second sub-module B, for example in the form of a half-bridge (for example, a half-bridge driver and two switches in series, see below Fig. 2 ), which generates an AC voltage supplied to the transformer 19 of the second sub-module B. The control unit G may have programming inputs, whereby a Programming or calibration programming of the control unit G is possible. For this, the terminals of the control unit G can be led out to the board of the second sub-module B, to allow programming of this sub-module B and thus the control unit G even after delivery of the sub-module B.

The second submodule B of the first module 12 denotes a galvanic decoupling via which the control unit G of the module 12 communicates with the submodule D as an interface circuit. This interface circuit D can have a data interface 11, which can be designed in particular for connecting an external analog or digital bus 10, for example in accordance with the DALI industry standard. Alternatively or additionally, however, it is also possible to transmit unidirectional or bidirectional signals at this data interface 11 or interface circuit D in accordance with other standards. Furthermore, alternatively or additionally signals can be received at this data interface 11 or interface circuit D which are generated starting from a manually actuated pushbutton or switch supplied by the data interface 11 or interface circuit D itself or externally (for example also via the input voltage 9).

The essential functions of the first module 12 are thus the provision (at the output of the second sub-module B) of a DC voltage (by rectifying the output voltage of the transformer 19 of the second sub-module B with the rectifier 22) starting from a supplied input voltage 9 and the external Communication via the data interface 11 or interface circuit D.

Preferably, spatially separated from said first module 12, a second module 1 is provided as a circuit module. This second module 1 has essentially the function of the so-called `lamp management`, which means that this second module 1 supplies on the one hand the connected lamps (here the LED segment 8 with one or more LEDs) with constant current and on the other hand feedback variables (schematically with 13 designated) from the area of the LED track 8 receives.

The DC supply voltage 5 at the output of the second submodule B of the first module 12 is thus supplied to a further submodule C as a controllable constant current source. This further submodule C thus supplies the LED path with constant current via an output 7. The second module 1 can in this case contain a plurality of converter stages (a plurality of further submodules C as constant current sources), wherein these converter stages (further submodules C as constant current sources) can each control separate (independent) LED paths 8.
The further submodule C can be called both a clocked constant current source (that is to say, for example, a buck converter also called a buck converter or an isolated flyback converter, also called a flyback converter). or be designed as a linear regulator (realized with transistors or integrated circuits).

Furthermore, the second module 1 has its own control unit E, which in turn acts as a microcontroller, ASIC or hybrid thereof may be formed. This control unit E of the second module 1 thus contains feedback variables 13 from the area of the LED track 8. The control unit E activates the one or more further submodules C in the second module 1. The current is controlled by the LED track 8, it can be detected and monitored for correct operation of the LEDs and error detection but also other feedback variables such as the LED voltage or temperature.

In a preferred embodiment, the further submodule C is designed as a clocked constant current source, this submodule C having at least one actively clocked switch SW1 as part of the clocked constant current source.

The actively clocked switch of the clocked constant current source is controlled directly or indirectly (for example via a driver module) by the control unit E. The use of a clocked constant current source, in contrast to a linear regulator allows flexible operation of different LED modules F. The clocked constant current source can adjust both the voltage and the current through the LED module F and adjust. The clocked constant current source is an actively clocked DC-DC converter, which receives the DC supply voltage 5 and the LED module F accordingly with the desired LED current and / or LED voltage feeds, preferably by a control by the control unit E. due to the feedback of this control unit E supplied.

The clocked constant current source further offers the advantage that the operating mode of the submodule C can be adapted to the respective current operating mode. Thus, the type of timing of the clocked constant current source can be adjusted, for example, the switch SW1 can be controlled with a frequency-modulated, pulse width modulated or a combination of Frequenzmoduliertem and pulse width modulated signal. The current operating mode may differ, for example, for operation at high brightness of the LED track 8 and at low brightness.

It is possible that several clocked constant current sources for feeding the LED sections 8, 8 ', 8 "on the outputs 7, 7', 7" are present. Preferably, the switches SW1, SW1 ', SW1 "of the individual clocked constant current sources are independently controllable by the control unit E. Thus, it is possible for each LED paths 8, 8', -8" to supply the individually required LED currents and LED It is also possible for a separate control unit E, E ', E "to be present for each of the clocked constant current sources with the switches SW1, SW1', SW1" is.

As previously mentioned, for proper operation of the LEDs and for fault detection, the control unit E may detect various feedback quantities (such as LED voltage, LED current, or temperature) and, preferably upon detection of a fault, switch the pulsed constant current source to an error operating mode. This can be done, for example, by a change in a burst mode or a low on-time operation of the switch SW1.

In addition, the control unit E via a bus line 6 (communication interface), which is designed in addition to the DC supply voltage 5, with the control unit G of the first module 12 are unidirectional or bidirectional in data communication. The bus line 6 can also be used to transmit the low-voltage supply (it then takes both a data communication and an energy transfer). The bus line 6 can also be integrated in the DC supply voltage 5, for example, the polarity of the DC supply voltage 5 can be switched or a carrier signal to the DC supply voltage 5 are modulated.

The control unit E can also transmit an error message and preferably also information about the type of error to the control unit G of the first module 12 via the bus line 6, for example in the event of an error detection by means of the bidirectional data communication.

As in FIG. 1 shown schematically, the second module 1, here as a lamp management module, preferably housed in a common housing 42 with the actual LED module F.

As in FIG. 1 shown schematically, the LED module F may have its own memory 4, for example in the form of an eprom. The reference numeral 3 is schematic indicates that the control unit E of the second module 1 can access this memory 4 of the LED module F.

With regard to the first module 12, it should be noted that the PFC circuit is optional only.

In addition, it should be pointed out that the illustrated functions of the submodules A, B and C can also be integrated circuit-wise, so that, as long as these functions are basically present, they do not have to be reflected in a corresponding structure of the circuit topology.

The advantage of the modular design according to Fig. 1 It is, for example, that the first module 12 and the second module 1 can be produced by different manufacturers. In addition, a plurality of second modules 1 in the sense of a master / slave operation can be connected to a first module 12. With the use of clocked constant current sources as submodule C, a two-stage system with a modular construction is thus created, wherein a plurality of second modules 1 can be connected to a first module 12 and also an operation of different LED modules F and / or a different operation of the same LEDs. Module F is made possible depending on the data bus 6 via the data communication.

Finally, the modular design also allows the respective sub-modules and in particular the second module 1 to be interchangeable while retaining the remaining components.

• Abgleich in der Fertigung oder bei der Inbetriebnahme
• ein geschlossenes Regelsystem innerhalb dieser Kombination (beispielsweise mittels eines internen Sensorsystems)
• Stützwerte
• Verfahren mit LED Charakterisierung
• oder eine Kombination aus den genannten Verfahren.

If the second module 1 is housed in a common housing 42 with the actual LED module F, there is the advantage that this combination of the second module 1 and LED module F can be adjusted in itself, so that, for example, their radiation characteristics, amount of light, Light color and / or light control parameterized and thus can be adjusted. The first module 12 and also the user can thus have one or more matched systems, which can then be controlled at the same time and behave accordingly. This internal balancing of the combination of the second module 1 and the LED module F can take place, for example, using one of the following methods:

• Adjustment in production or during commissioning
• a closed control system within this combination (for example by means of an internal sensor system)
• supporting values
• Procedure with LED characterization
• or a combination of the said methods.

The communication between the first module 12 and the second module 1 via the bus line 6 is accordingly preferably standardized.

From the outside, for example via a bus line of the external bus 10 via the data interface 11 incoming commands or queries are supplied as shown only the first module 12. This can thus be referred to as external data communication, in contrast to the internal data communication via the bus line 6 between the first module 12 and the second module 1.

This has the advantage that for adaptation to different external buses 10 only the first module 12 is to be adapted, while the structure and the data protocol for the second module 1 remain unaffected.

The communication via the internal bus line 6 is thus also standardized, since it is independent of different bus protocols or control signals which can be applied to the first module 12.

The communication via the internal bus 6 combined with the modular design of the system provides the advantage that the operating data for the optimal feeding of the second module 1 can be transmitted from the second module 1. The second module 1 (preferably starting from the control unit E) can transmit the required operating data via the internal bus 6 to the first module 12. This offers the advantage that a first module 12 can be combined with many different second modules 1, wherein the required operating data can be read from the second module 1.

Examples of the feedback quantities 13 from the LED track 8 are the directly or indirectly measured LED current and / or the voltage across the LED track 8.

In the memory 4, which is assigned to the LED module F, operating data for the LEDs of the LED track 8 can be stored, for example, at the manufacturer. This data in this memory 4 may thus be, for example, characteristic values, the permissible maximum values for current and / or voltage, temperature dependence of electrical or optical (spectra) parameters of the LEDs, etc. These operating data for the LEDs (for example, data from the memory 4) can be transmitted via the internal bus 6 to the first module 12.

As already briefly stated above, a first module 12 in the sense of a master can supply a plurality of second modules 1. This means that a single first module 12 not only supplies several second modules 1 with a DC supply voltage 5, but also communicates with these bidirectionally in the sense of an internal bus line 6.

As already explained briefly above, the control unit G in the first module 12 can control the second sub-module B, which is preferably clocked. The same control unit G or preferably also a further control unit (not shown) can also regulate the operation of the PFC of the first submodule A, ie for example activate the switch of the PFC of the submodule A and for signals from the area of the PFC, such as the input voltage Current through an inductance of the PFC, the current through the switch of the PFC, the output voltage of the PFC, as indicated schematically by arrows in FIG Fig. 1 , is shown.

The PFC may be, for example, a boost converter (boost converter), flyback converter (buck-boost converter, an isolated flyback converter) or SEPIC converter.

Typically, the output voltage (bus voltage) Vbus of the PFC of the first sub-module A is in a range of several hundred volts DC. Due to the Transformer 19 in the second sub-module B can thus be lowered, this DC voltage, for example, to a voltage in the range of 20 to 60 volts, preferably 40 to 50 volts DC. Thus, after the output of the first module 12, the DC supply voltage 5 is at a lower level than the voltages internally prevailing in the first module 12, which, for example, limits the isolation of the DC supply voltage 5 to that of the second module 1 and to the second module 1 even lower claims. In addition, optionally, a second output voltage, for example a DC low-voltage supply for the second module 1, can be generated in the first module 12 and provided to the second module 1.

An advantage of the modular design with internal bus line 6 as described above is that the second module 1 (or in the presence of a plurality of second modules 1 at least some of these) can be switched off, while the first module 12 is still responsive to the bus line 6 or possibly . can also send 6 messages via the bus line. Thus, the first module 12 may perform emergency light detection (switching from AC to DC supply or rectified AC supply). Moreover, the control unit G, for example as a microcontroller, of the first module 12 in this idle state can be powered only via the external bus 10 when the idle state of the external bus 10 (such as DALI) is not equal to 0 volts. Thus, it is possible to use an energy transmitted via the external bus 10 to supply the control circuit G (in particular as start-up energy for the control circuit G or a low-voltage supply supply circuit). Consequently the actual power supply of the first module 12 can be switched off in this idle state. It is also possible that only a wake-up signal is sent via the external bus 10, which provides a starting energy as a power for short-term supply for the control circuit G or a low-voltage supply circuit. In this case, the first module 12 can be completely put into a resting state without energy consumption. The wake-up signal may also be a data transmission or a momentary connection of a voltage.

Of course, if several second modules 1 are supplied by a first module 12 (central module), selectively selected ones of these several second modules 1 can be switched off. This also leads to a saving of electrical losses. For example, in the emergency case, it can be provided that only one or a subset of the plurality of second modules 1 supplied by the first module 12 is operated to achieve the lower basic brightness for the emergency lighting operation.

With the common housing 42, a passive or preferably active, in particular controlled by the control unit E sensing means 40 is connected, for example. A fan or a cooling unit.

In addition to the bus line 6, the second module 1 (lamp management module) may also have an additional interface (not shown). This additional interface can be designed, for example, wired or wireless. For example, data from the second module 1 are read, in particular for maintenance purposes, such as the replacement of a second module 1. It can also be an update of the data or control software on this additional. Interface, in particular in a wireless communication. It may also be possible to read in particular data from this second module 1 via this additional interface even in the absence of DC supply voltage 5 (power transmission) for the second module 1. Preferably, the additional interface is arranged on the second module 1 spatially separated from the bus line 6.

Referring to FIG. 2 now the bus line 6 (internal bus) between the first module 1 and one or more second modules 1, 1`.all be referred to as lamp management modules or operating devices.

Due to the fact that several second modules 1, 1 'are connected via the internal bus not only with power (transmission path 5) but also with unidirectional or bidirectional data exchange (bus line 6), the central control unit (also called first module) 12 also be referred to as a central unit or master. The second modules 1, 1 'can be referred to as slaves.

As already mentioned, with regard to the internal bus, a preferably standardized communication is provided for the bus line 6, which is provided in addition to the DC supply voltage 5. By "standardized" is meant that the protocol of the bus 6 is independent of the protocol of the external communication via the data interface 11 of the first module 12.

Preferably, the communication via the bus line 6 is bi-directional and, for example, according to the one SPI protocol (Serial Peripheral Interface Bus) done.

The data communication via the bus line 6 (internal bus) is preferably electrically isolated, for example using optocouplers or transformers. For example, when using one or more transformers for a floating bus 6, the transformer can be clocked high-frequency and thus transmit data via packets of high-frequency clocks. By using a floating bus line 6, the user and also the other connected modules can be protected against possible overvoltages, for example due to a defect in one of the modules. The potential-separated design of the bus line 6 also increases the robustness of the illumination system, for example, the separation and replacement of a second module 1 is facilitated.

A basic function of the bus line 6 may be the passing of dimming commands from the first module 12 to the second modules 2, which have been received via the external bus 10, for example. In this case, new control information or commands for the second modules 1 can also be derived from the dimming commands received via the external bus 10.

One application for bidirectional data communication via the internal bus (bus line 6) is that data stored in one of the second modules 1, 1 'is transmitted via the internal bus (bus line 6) to the control unit G of the first module 12 can be. This is advantageous in that the data storage in the second modules 1, 1 'is closer to the LED track 8, so that there takes place a higher heating, which leads to a possibly irreproducible loss of data storage in the area of the lamp management modules ( second modules 2, 2 ') can follow. Even by the transmission via the bus line 6 to the first module 1, these data can then be the first module 12 in the sense of a backup again stored.

Examples of this data transmitted via the bus line 6 are operating data for the LED route 8, such as temperatures, operating times, electrical parameters, etc.

After the data have been transferred from one of the lamp management modules (second modules 1, 1 ',..., In') to the first module 12, they can, of course, be further processed and also read out via the external bus 10 connected to the data interface 11. Thus, via the external bus 10, a further analysis of the operating data, for example a failure analysis, an aging compensation depending on the transmitted operating time duration of the LED route 8, etc., take place.

The standardized approach for the internal bus (bus line 6) also has the advantage that lamp management modules (second modules 1, 1 ') can be exchanged in a simple manner. The data stored in a lamp management module (second modules 1, 1 ') to be exchanged can be stored in the first module 12 already described above after transmission via the bus line 6. Then, when the lamp management module is replaced, the operating data stored in the first module 12 can be transferred back to the newly deployed lamp management module so that it is then configured identically to the replaced lamp management module.
Further examples of such operating data are color coordinates, color coordinates or other parameters influencing the spectrum of the LED route 8.

Load changes or special operating states or comparable events from a second module 1, 1 'can also be transmitted via the bus line 6 to the first module 12 via the bus line 6. It can thus be a Vorabsignalisierung of expected load changes or operating state changes, so that the control unit G in the first module 12, the control of the PFCs in the first sub-module A and / or the control of the second sub-module B adaptively adaptively. For example, depending on a via the bus 6 from a second module 1, 1 'transmitted expected load change or operating state change, the control unit G of the first module 12 parameters for in FIG. 2 shown inverter 14 and / or adjust controller characteristics for the control of the PFCs in the first sub-module A.

Of course, some kind of prior information may be reversed, i. from the first module 1 to the second modules 1, 1 'take place. If, for example, the first module 12 receives dimming commands via the external bus 10 and the data interface 11 or the interface circuit D, which indicate a load change of the LED route 8, such information or a signal representing the operating state change can be transmitted via the bus or the bus line 6 are transmitted to the second modules 1, 1 ', so that the control unit E provided in the second modules 1, 1' can also adapt control parameters, for example for the constant current source (further submodule C), in accordance with the expected load change.

This in FIG. 2 shown master / slave system also has advantages in terms of reducing electrical losses, since a kind of standby mode can be provided in which one, several, or even all of the second module 1, 1 'connected to a first module 12 are turned off, while at least the control unit G of the first module 12 can continue to monitor the externally connected bus 10 via the data interface 11 or the interface circuit D.

Externally this is in the FIG. 2 illustrated master / slave system preferably only via the connected to the data interface 11 and the interface circuit D of the first module 12 bus 10 responsive. However, there may be an internal hierarchical distribution, possibly including addressing via the internal bus (bus line 6) to the plurality of connectable second modules 1, 1 '. Thus, on the one hand, an addressed communication can take place towards the second modules 1, 1 '. Alternatively or additionally, however, a broadcast mode can also be provided, ie an undressed data transmission from the first module 12 to all connected second modules 1, 1 '. In this broadcast mode, a command transmitted by the first module 1 via the internal bus (bus line 6) is received and evaluated by all second modules 1, 1 '.

In the emergency light case, it can be provided that as soon as an emergency light recognition has taken place by the first module 12, a corresponding control command is transmitted via the bus line 6 and the second modules 1, 1 'adjust according to their operation. For example, in order to achieve a lower basic brightness and thus a lower energy consumption for emergency lighting operation, only one or a subset of the plurality of second modules 1 supplied by the first module 12 can be operated.

The bus line 6 can also be used to transmit the low-voltage supply (then there is both a data communication and a power transmission, for example via the secondary-side DC low-voltage power supply VCCs). For example, a so-called active low data transmission can be used, wherein at rest, a level of a few volts, for example 12V, is applied. In the case of a coupling, for example via transformers, energy could nevertheless be transmitted even if the bus line 6 were electrically isolated.

In the Fig. 3 is a possible embodiment of the bus 6 shown. There is a channel CLK for the output of a clock signal and a further channel for transmitting, the transmission channel SD, for transmitting signals. Furthermore, a return channel BCK is present, via which the connected operating devices 1 can emit a return signal.
In this bus 6 further operating devices such as the operating device 1a can be connected during operation.

In the Fig. 4 an embodiment of the sequence of signal transmission is shown in normal operation, in which case no error feedback of a control gear takes place. A clock signal (CLK) is regularly emitted by the central control unit 12 on an internal bus (6), via which the operating devices (1, 1 ', 1''..) are controlled by means of commands from a central control unit (12). The operating devices send back the clock signal on a back channel (BCK) of the internal bus, provided there is no error.

The signals transmitted on the internal bus are formed, for example, from pulse packets which are composed of several high-frequency pulses.

In the Fig. 5 an embodiment of the sequence of assigning the addresses according to the invention is shown, wherein an error first occurs.

If a further operating device (1a) is connected to the central control unit (12), an error signal is transmitted on the back channel (BCK). the internal bus through the switched-on operating device (1a), this error signal is not sent in synchronism with the clock signal (CLK). The central control unit (12) can now recognize this return signal as an error signal.

Since it has thus been recognized that a new operating device has been connected which does not yet have an address, now the assignment of addresses (A) for the connected operating device (1a) by the central control unit (12) can begin.
It can also restart the LED
Lighting system done and an address assignment for all connected operating devices (1, 1a) done.

In this case, an addressing by means of collision detection can take place, with the individual operating devices switching on or off or also reporting back depending on an internally generated random number on the internal bus 6. For example, a loading of the central control unit (12) by connecting the operating devices (1, 1 ', 1''.. ..) take place, with a delayed connection or disconnection of the operating devices (1, 1', 1 '' ..) takes place, each operating device (1, 1 ', 1''.. ..) the. Delay time for switching on or off based on a random number sets and the connection or disconnection by the central control unit (12) is detected and assigning addresses (A) for the operating devices (1, 1 ', 1 "..) by the Central control unit (12), wherein the allocation of the addresses (A) of the detected order in the connection or disconnection of the operating devices (1, 1 ', 1 "..) is dependent.

For example, a simultaneous feedback of two operating devices can take place at the first feedback. In a further step, the central control unit 12 to query the possible addresses A and check transmits an acknowledgment for a particular address more than one operating unit 1, 1 ', 1'',1' ^x 1 ^'y.

This method can be used to detect address conflicts. Now, the checking operation for the remaining addresses A is performed according to the same method. Further, the central control unit 12 can query the possible addresses so long as A and check to possible all addresses for not more than one operating unit 1, 1 ', 1'',1' ^x 1 ^'y sends a response. In a further step, the central control unit 12 can evaluate the responses and check for transmission errors.

The central control unit 12 may have an interface 10 and communicate via this interface, for example, according to the DALI standard.

The central control unit 12 can query the possible addresses A and check that sends a response for a particular address more than one operating unit 1, 1 ', 1 ", 1' ^x 1 ^'y.

Claims (9)

1. Method for connection detection for an LED lighting system, wherein the LED as lighting means are controlled by at least an operating device (1, 1', 1 "..) depending on commands from a central control unit (12),
   characterized by the following steps:

   - supplying the operating devices (1, 1', 1"..) with voltage via the central control unit (12),

   - transmitting a clock signal (CLK) on an internal bus via which the operating device (1, 1', 1"..) is controlled by means of commands from a central control unit (12), wherein the operating device sends back the clock signal on a back channel of the internal bus,

   - switching a further operating device (1 a) to the central control unit (12),

   - transmitting an error signal via the back channel (BCK) of the internal bus through the switched operating device (1 a), wherein this error signal is not transmitted synchronously with the clock signal (CLK),

   - detection of the error signal by the central control unit (12)

   - assigning addresses (A) for the switched operating device (1a) through the central control unit (12).
2. Method for connection detection for an LED lighting system according to claim 1,
   characterized in that
   the central control unit (12) puts the operating device (1, 1', 1"..) in an addressing mode, and then begins the assignment of addresses at least for the switched operating device (1 a).
3. Method for an LED lighting system according to claim 1 or 2,
   characterized in that
   the central control unit (12) polls and checks the possible addresses (A) until all possible operating devices (1, 1', 1".. ) have been assigned an address (A).
4. Method for an LED lighting system according to any one of the claims 1 to 3,
   characterized in that
   the operating device, which was first assigned an address (A), is assigned the status of a master.
5. Method for an LED lighting system according to claim 4,
   characterized in that
   the other operating devices, which were not first assigned an address (A), are assigned the status of a slave.
6. Method for an LED lighting system according to claim 1 to 5,
   characterized in that
   the operating devices (1, 1', 1"..) monitor whether a collision occurs with respect to the addressing upon the feedback.
7. LED lighting system (BA) with at least a lighting means, wherein the lighting means are controlled by at least an operating device (1, 1', 1 "..) depending on commands from a central control unit (12), wherein the operating device (1, 1', 1"..) is supplied with a voltage through the central control unit (12) and the operating devices (1, 1', 1"..) comprise an address (A),
   comprising an internal bus via which the operating devices (1, 1', 1"..) are controlled by means of commands from the central control unit (12), wherein the central control unit (12) transmits a clock signal (CLK) and the operating devices send back the clock signal via a back channel of the internal bus,
   characterized in that
   a renewed assignment of the address (A) assigned to the operating device (1, 1', 1 "..) takes place as soon as an error signal is sent back via the back channel of the internal bus through the switched operating device (1 a), wherein the error signal sent back via the back channel of the internal bus, is sent as a signal that is not synchronous with the clock signal (CLK),
8. LED lighting system (BA) with at least a lighting means according to claim 7,
   characterized in that
   after receiving an error signal via the back channel of the internal bus, the central control unit (12) performs a restart.
9. LED lighting system (BA), with at least a lighting means according to one of the claims 7 to 8
   characterized in that
   the signals of pulse packets transmitted on the internal bus are formed from a plurality of high-frequency pulses.

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