EP2067379A1 - Lamp operating device for operating one or multiple light sources, and method for operating a lamp operating device - Google Patents

Abstract

The invention relates to a lamp operating device (10) for operating one or multiple light sources (20-1, 20-2), with a first interface unit (15) for connecting the lamp operating device (10) to a control line (2) and for receiving external control commands corresponding to a first communications protocol, and with a control unit (11) which operates the light source(s) (20-1, 20-2) in accordance with the control commands received via the first interface unit (15). A second interface unit (17) is provided for receiving programming information according to a second communications protocol, wherein the conversion of the control commands received via the first interface unit (15) for operating the light source(s) (20-1, 20-2) is performed by the control unit (11), at least partially taking into account the programming information.

Description

 A lamp operating device for operating one or more light sources and method for operating a lamp operating device

The present invention relates to a lamp operating device which is provided for operating one or more light sources and has a first interface unit, via which external control commands are transmitted to the lamp operating device. Furthermore, the present invention relates to a method for operating a corresponding lamp operating device.

In modern lighting systems, luminaires are often used whose light effect can be changed depending on the wishes of a user of the lighting system. In a simple embodiment, for example, there is the possibility of remotely switching on and off the lights and to vary their brightness. In particular, the idea has recently prevailed to control the luminaires for brightness control by means of digital commands.

This digital control of luminaires or lamp operating devices associated with the luminaires for operating the light sources has been facilitated in particular by the development of the so-called DALI (Digital Addressable Lighting Interface) standard. It is a digital lighting control standard that offers increased convenience for intelligent lighting control compared to previous lighting control methods - such as the familiar 1-10 volt interface. The DALI standard represents a new interface definition, which was developed in particular for the control of electronic ballast (ECG) for the operation of gas discharge lamps. Within the scope of this standard, the operation of electronic ballasts - or even of other lamp operating devices - can be carried out in digital form, with the possibility in particular of controlling lamp devices via addresses assigned to them individually or in groups and of adjusting the brightness of their associated light sources. Other standards (for example DMX) for driving lamp operating devices are also known.

The aforementioned DALI standard was primarily developed to provide brightness control of the light sources. Accordingly, one stands limited set of control commands, which relates in particular to the brightness control of the light sources. In the meantime, however, modern luminaires open up the possibility of setting other parameters. Thus, luminaires are known in which not only the total intensity of the emitted light can be influenced, but also the emission direction, the light distribution or the color of the emitted light. For example, a color control or color temperature control is made possible in a simple manner in that the luminaire has a plurality of differently colored light sources, wherein the light sources can each be individually adjusted in their brightness in order to achieve a mixed light in a desired hue.

A remote color change of the light of individual lights using the DALI instruction set is now not readily possible, since a corresponding adjustment in the development of the DALI standards was not originally provided. Although a color control could be made possible by the fact that each color is assigned its own address, so that then the individual colors are changed individually with corresponding control value commands. However, this would mean that a single luminaire occupies a plurality of fictitious addresses in a larger illumination system, which impairs the clarity when driving the light sources. Furthermore, the known light control systems have only a limited address space. This means that only a certain number of luminaires can be controlled individually. If the luminaires which can be changed in color would be assigned several addresses according to the bypass solution described above, this would result in a considerable reduction of the controllable luminaires.

Another problem is that the known control systems for lighting control systems are only limited suitable to be able to easily program lights in which different parameters are adjustable. Operation is often based on simply recalling pre-programmed scenes or

Limited processes, which is why the complex setting of modern lights is difficult to make.

The present invention is therefore based on the object to provide a way even more modern lights, which offer a variety of settings, to control in the context of known lighting control systems. In particular, the possibility should be opened to operate such lights within the framework of the known DALI standard. The object is achieved by a lamp operating device with the features of claim 1 or a method for operating a corresponding lamp operating device. Advantageous developments of the invention are the subject of the dependent claims.

The solution according to the invention is based on the idea of programming the lamp operating device in such a way that a more complex setting of light-specific parameters is also made possible with the aid of the DALI standard or, in general, a command set for the digital activation of luminaires. In addition to a first interface unit which is provided for receiving the digital control commands, therefore, the lamp operating device according to the invention has a further interface unit for supplying programming information, the programming information is used to the behavior of the lamp operating device when driving the associated light source or light sources in dependence on the received control commands to the

Adjust available settings. In this way, it is possible to customize the way in which the incoming external control commands are interpreted by the lamp operating device and converted to drive the light source (s). Accordingly, the available commands can now also be used to date, not previously provided

Make adjustments to the associated light sources, for example, adjust their color or emission characteristics.

According to the invention, a lamp operating device for operating one or more light sources is accordingly proposed, which comprises: a) a first interface unit for connecting the lamp operating device to a control line and for receiving external control commands in accordance with a first communication protocol; b) a control unit which operates the light source (s) in response to the control commands received via the first interface unit, and c) a second interface unit for receiving programming information in accordance with a second communication protocol, the conversion of the control commands received via the first interface unit for operation the light source (s) is performed by the control unit at least partially taking into account the programming information.

Furthermore, the invention proposes a method for operating a lamp operating device for one or more light sources, wherein external control commands for operating the light sources are transmitted to the lamp operating device via a first interface unit according to a first communication protocol, and wherein the control of the light sources according to the received control commands at least partially taking into account programming information, which transmits the lamp operating device via a further interface unit according to a second communication protocol were.

The second interface unit can be designed, for example, to be connected to a data transmission line which is separate from the control line and which carries the

Connection of a programmer, especially a PC allows. For this purpose, the second interface unit can represent, for example, a USB interface or an RS232 interface. A wireless reception of the programming information via the second interface unit would also be conceivable, this then preferably being in the form of a Bluetooth or infrared interface.

The first interface unit, in turn, is configured to receive control commands in accordance with a first communication protocol, which may be commands in accordance with the DMX standard, for example. Preferably, the interface unit is adapted to receive control commands according to the DALI standard. The programming information transmitted to the lamp operating device according to the invention can then be used to assign a new function to certain commands of the DALI standard. Depending on the type of light sources to be controlled, this means that individual DALI commands can now be used specifically for influencing certain parameters of the luminaire.

The programming information in this case preferably relates in particular to the interpretation of the control unit with regard to the so-called scene commands available in the DALI standard. These commands are initially used to tell a luminaire to assume a specific, preset level of brightness. By appropriate programming of the lamp operating device, however, an extended function is now assigned to these commands to the effect that other parameters of the luminaire can also be changed hereby. For example, using the programming information, a set of certain

Parameter values are stored, which affect not only the brightness of the light source but also their color, their emission direction and / or their light distribution. When transmitting the corresponding scene command via the control line of the DALI bus is now so not only in a simple way, the brightness of the Light source changed, but also made a change in the other parameters of the light source. The advantage of this procedure is that the already available DALI standard scene commands are now used to individually exploit the setting options of the corresponding light source. In this way, the integration of novel lighting is facilitated in existing lighting systems, since the control of the existing lights can be made in the conventional manner, without this would be associated with any restrictions. Accordingly, the present invention opens up the possibility of being able to operate remotely controlled novel lights or light sources in a simple manner.

The invention will be explained in more detail below with reference to the attached drawing, in which:

Fig. 1 shows schematically the overview of a lighting system in which the lamp operating devices according to the invention are used;

Fig. 2 shows the detailed structure of a lamp operating device according to the invention and

3 and 4 embodiments of stored in programming the lamp operating device parameter sets.

Fig. 1 shows a generally provided with the reference numeral 1 control system for operating lights, in which the inventively designed lamp operating devices are used. Shown in the present case are two lamp operating devices 10-1 and 10-2, which are each provided for driving a light source 20-1 or 20-2 associated therewith. In the illustrated embodiment, the light sources are radiators, which - as described in more detail below - offer special adjustment options, although the present invention is basically applicable to all types of luminaires.

The lamp operating devices 10-1, 10-2 are connected to a common control line 2, which forms a bus line of the control system 1. Via this control line 2 the lamp operating devices 10-1, 10-2 digital commands are transmitted, which are then implemented by the devices 10-1, 10-2 for driving the radiators 20-1 and 20-2. These digital control commands can be transmitted, for example, from a central control device 3. This may be a unit located in a central room of a building to be illuminated, which automatically and time-dependently transmits specific brightness commands or general control commands to the lamp operating devices 10-1, 10-2. Furthermore, a decentralized control of the lamp operating devices 10-1, 10-2 would also be possible, for which purpose manual input units 5 are arranged in the individual rooms. These units have a display and input elements 6 and 7, via which certain parameters of the light sources 20-1 and 20-2 can be changed manually.

Lighting systems enabling such control via digital commands are already known in the art. They open up an automated and comfortable setting of the various light sources and are therefore used in particular for illuminating larger buildings or facilities. The generation and transmission of the digital

Control commands via the control line 2 are carried out according to a predetermined Kornmunikationsprotokoll, in particular, the protocol according to the so-called. DALI standard can be used. It is an interface definition developed by the leading lamp operating equipment developers to enable centralized control of distributed light sources. The DALI standard defines a number of different digital commands that allow individual light sources to be addressed individually or in groups with the help of addresses assigned to them in order to cause them to switch on or off and in particular to change their brightness.

By means of the commands made available by the DALI standard, there is thus in particular the possibility of switching on and off or dimming light sources. The light sources 20-1 and 20-2 illustrated in FIG. 1, however, offer setting possibilities that go beyond dimming and that can not be readily used with the help of the DALI commands.

Thus, the light source 20-1 is an RGB emitter, which has three different-colored individual light sources 21, 22, 23 in the form of LEDs or generally of light-emitting semiconductor elements, which are individually adjustable in their intensity. By selecting the ratio of the light intensities of the three light sources 21, 22, 23 a variable in its color mixed light is generated, which is ultimately emitted by the radiator 20-1. The commands available in the DALI standard have so far not allowed, in a simple way a Adjusting the color of the emitted light from the radiator 20-1. While it would be possible to assign each individual light source 21, 22, 23 each a separate address and then to control them individually, but this is a relatively complex solution to the problem. A further disadvantage is that, accordingly, the lamp operating device 10-1 would have to be provided with a multiplicity of virtual addresses in order to carry out a color control. However, since the number of total addressable lights in the DALI standard is limited, this would result in a reduction of the total usable or controllable lights.

A similar problem exists in the second light source 20-2, which is a radiator, which is indeed provided with only a single light source 24, but in addition to an anchor point 25 is pivotable to adjust the light output in a desired direction. Also for this adjustment, which should be made by the lamp operating device 10-2, no special commands are provided in the DALI standard. Although it would be conceivable in this case, make the pivoting of the radiator 20-2 via an additional virtual address, but this would in turn connected to the disadvantages described above.

To avoid this problem, the invention provides that the lamp operating devices 10-1 and 10-2 are specially programmed to use the new settings for the light sources 20-1, 20-2 in the DALI standard. This will be explained in more detail below with reference to FIG. 2, which shows the specific embodiment of the first lamp operating device 10-1.

The lamp operating device now generally provided with the reference numeral 10 initially has a control unit 11 which is provided for driving the three differently colored individual light sources 21, 22, 23 and has corresponding outputs 12, 13, 14. Via these outputs 12, 13, 14, the light sources 21, 22, 23 transmitted corresponding control signals to adjust them in the desired manner in their brightness. The control takes place in accordance with the control commands, which are transmitted via the control line 2 to the lamp operating device 10. For this purpose, the lamp operating device 10 has a first interface unit 15, which is connected via a corresponding terminal 16 to the control line 2. In this case, the interface unit 15 is designed to receive data according to a first communication protocol-in the present case according to the DALI standard-and to forward it to the control unit 11, which then then carries out the control of the light sources. In that regard, the embodiment of the lamp operating device according to the invention of those already known devices. What is new is now a second interface unit 17, which is connected via a second connection 18 to a further control line 9 and designed to provide data in accordance with a second

Receive communication protocol. These data are in particular programming information, which in turn is transmitted from the second interface unit 17 to the control unit 11. In particular, this data may be provided by a programming device, e.g. come from a personal computer (PC) 8, over which in a programming mode, an individual programming of the lamp operating device 10 can be made.

The interface unit 17 can be designed, for example, as a USB interface or as an RS232 interface in order to be connected to the PC 8 via the control line 9. However, a wireless communication between programming device or PC 8 and the interface 17 would also be conceivable. In this case, the interface unit 17 could also be implemented as a Bluetooth interface or as an infrared interface.

The programming information received via the interface unit 17 is now used to influence the behavior of the control unit 11 when driving the light sources 21, 22, 23 as a function of the control commands received via the first interface unit 15. In particular, the programming information is used to notify the control unit 11 how to respond to the incoming

Control commands should be responded to, so how they are to be interpreted in order to control the individual light sources 21, 22, 23.

In the present embodiment, in which the control of the lamp operating devices 10 takes place by means of DALI commands, this means that at least a part of the DALI commands a new function or meaning is assigned, which relates in particular to the setting of the additional parameters of the light source (s). Thus, individual commands can now be used to influence the mixed color generated by the three light sources 21, 22, 23 or to cause the emitter 20-2 to pivot.

In the case of using the DALI standard, the programming information transmitted according to the invention is used, in particular, to influence the meaning of the scene commands of the DALI standard in order to provide further control options open. The scene commands of the DALI standard are originally intended to give the luminaires certain brightness values that they should adopt in certain situations. In order to avoid a complex and individual control of the individual light sources at a later time, such scenes are already stored in advance in the memory of the lamp operating device, in which case at a later time only the device is informed that it should behave in accordance with one of the stored scenes , According to the data stored in the memory, the lamp operating device then assumes a certain operating mode and drives the light sources with a desired brightness.

In a preferred exemplary embodiment of the present invention, it is now provided that these scenes are assigned extended parameter sets which relate not only to the brightness of the light source but also to the other setting options and are stored in a memory 19 of the lamp operating device 10. In the illustrated embodiment, the memory 19 is part of the control unit 11, but of course it would also be possible to form this memory 19 as a separate element within the lamp operating device 10.

FIGS. 3 and 4, which will be explained in more detail below, show such parameter sets as are used according to the particularly preferred embodiment of the present invention. FIG. 3 shows, for example, the memory content of the memory arranged in the lamp operating device 10-1 for driving the RGB radiator 20-1, while FIG. 4, by way of example, shows the parameter sets for controlling the pivotable radiator 20-2.

Since the DALI standard offers the possibility of storing a maximum of 16 scenes in advance, the table shown in FIG. 3 accordingly contains 16 parameter sets. Each parameter set now provides information about the intensity of the light emitted by the emitter as a whole and about the proportions of the individual colors. The first parameter set (scene 1) thus corresponds to a maximum brightness of the radiator, wherein the proportions of the different colors are the same, so that finally white mixed light is emitted. On the other hand, in scenes 2, 3 and 4, a maximum brightness is likewise provided, but this is achieved in each case by a single one of the three colors. These scenes thus correspond to a maximum light output, each with a single color. The scene 16, in turn, is assigned a parameter set according to which the total intensity is 50% of the maximum brightness, the red portion being opposite to the green and blue portions predominates. So a mixed light is given, which contains a reddish tone.

The writing of these parameter sets can be made in a simple manner by the PC 8, to be entered with the help of an appropriate program including a suitable graphical user interface various settings and then transferred directly to the lamp operating device 20. The resulting effect on the light output by the radiator 20-1 can thus be checked immediately. In this way, it is possible to form individual sets of parameters and to transmit them to the lamp operating device 10, wherein individual sets can also be connected to one another over a time sequence, in order thereby to form a specific light sequence. A parameter set or a corresponding sequence is then assigned to a desired scene number and stored in the memory. It should be noted that in the example in FIG. 3, the parameter values are not used for different angle settings and for the light distribution, since the radiator does not offer such adjustment possibilities.

In the same way, the programming of the second lamp operating device 10-2 takes place, whereby the memory contents according to FIG. 4 now contain a different parameter combination, since the emitter does not offer a possibility for color change, but does allow a change of direction of the light output or adjustment of the distribution characteristic , While the angles α and β in this case define a pivoting of the radiator in space, the value "distribution" influences, for example, the size of the light cone. The parameter set of scene 1 corresponds to a maximum light output at a non-displaced spotlight and a beam of maximum width. The other scenes 2 to 16 in turn define different positions of the radiator and different widths of light cone.

After programming, the PC 8 can be separated from the lamp operating devices 10 and thus the programming mode can be terminated. In the later normal operation of the control system 1, the lamp operating device 10 is thus connected exclusively to the control line 2 of the DALI bus with the operating devices 3 and 5 exclusively with the aid of the first interface unit 15. These devices 3, 5 now have the ability to retrieve individual scenes in the preprogrammed lamp control units 10, for which purpose the scene selection commands available in the DALI standard are used. In this way, therefore, the individual settings that have been stored in the memory 19 can be retrieved to make settings of the radiator 20-1, 20-2. The scene commands will be added in this case used not only to retrieve the preset brightness of a light sources, but instead to make a color selection or a direction setting of the spotlight.

One advantage of the solution according to the invention is that the classic DALI instruction set can still be used to control the various lamp operating devices. Each luminaire unit newly added to the system can be individually programmed to adjust the luminaire-specific parameters as part of the scene commands. The control of the other lights already in the system is not affected by this. Accordingly, it is also possible to add completely novel luminaires in a simple manner and, nevertheless, to control them in a comfortable way. It should be added that, of course, other instruction sets could be used instead of the DALI instruction set for data transmission according to the first communication protocol. For example, a drive according to the DMX standard would also be possible.

Claims

claims

A lamp operating device (10) for operating one or more light sources (20-1, 20-2), comprising a) a first interface unit (15) for connecting the lamp operating device (10) to a control line (2) and receiving external control commands accordingly a first communication protocol, b) a control unit (11) which operates the light source (s) (20-1, 20-2) in dependence on the control commands received via the first interface unit (15), c) a second interface unit (17) to receive

Programming information according to a second communication protocol, wherein the conversion of the control commands received via the first interface unit (15) for operating the light source (s) (20-1, 20-2) by the control unit (11) takes place at least partially taking into account the programming information.

2. Lamp operating device according to claim 1, characterized in that the second interface unit (17) for connection to one of the control line (2) separate data transmission line (9) is formed.

3. Lamp operating device according to claim 2, characterized in that the second interface unit (17) is a USB interface.

4. Lamp operating device according to claim 2, characterized in that the second interface unit (17) is an RS232 interface.

5. Lamp operating device according to claim 1, characterized in that the second interface unit (17) is designed for wireless reception of the programming information.

6. Lamp operating device according to claim 5, characterized in that the second interface unit (17) is a Bluetooth or infrared interface.

7. Lamp operating device according to one of the preceding claims, characterized in that it has a plurality of control outputs (12, 13, 14) for driving different colored light sources (21, 22, 23).

8. Lamp operating device according to one of the preceding claims, characterized in that it has a control output for driving a Verstellvorichtung for the light source.

9. Lamp operating device according to one of the preceding claims, characterized in that the first interface unit (15) is designed to receive control commands according to the DALI standard.

10. Lamp operating device according to claim 9, characterized in that the programming information concerning the implementation of scene commands of the DALI standard by the control unit (11).

11. Lamp operating device according to claim 10, characterized in that it comprises a memory (19) for storing parameter sets, each defining different settings of the light source (s) and each associated with a scene.

12. Lamp operating device according to claim 10, characterized in that a plurality of parameter sets are combined to a temporal sequence, wherein this sequence is associated with a single scene.

13. Control system for operating lights with a control device (3, 5) for generating control commands, to the control device (3) connected control line (2) and at least one likewise connected to the control line (2) lamp operating device (10,) characterized in that the lamp operating device is designed according to one of the preceding claims.

14. A method for operating a lamp operating device (10) for one or more light sources (20-1, 20-2), the lamp operating device (10) via a first interface unit (15) according to a first communication protocol external control commands for operating the light sources (20 - 1, 20-2) are transmitted, and wherein the control of the light sources (20-1, 20-2) in accordance with the received control commands at least partially taking into account programming information, which the lamp operating device (10) via a further interface unit (17) transmitted according to a second communication protocol.

15. The method according to claim 14, characterized in that the transmission of the control commands takes place according to the DALI standard.

16. The method according to claim 15, characterized in that the programming information relating to the implementation of scene commands of the DALI standard.

17. The method according to claim 16, characterized in that it comprises a memory (19) for storing parameter sets, each defining different settings of the light source (s) and each associated with a scene.

18. The method according to claim 17, characterized in that a plurality of parameter sets are combined to form a temporal sequence, this sequence being associated with a single scene.

19. The method according to claim 17 or 18, characterized in that at least some of the parameters relate to a color control of the light source (s) (20-2).

20. The method according to any one of claims 17 to 19, characterized in that at least a part of the parameters relates to a positioning and / or influencing the light emission of the light source.

21. The method according to any one of claims 14 to 20, characterized in that the transmission of the programming information in a programming mode of the lamp operating device (10).