EP2319278A2 - Method for actuating an operating device for illuminating unit, particularly led - Google Patents

Abstract

A method for actuating an operating device (1) for an illuminating unit, particularly LED, wherein the operating device can receive digital control commands according to at least two different transmission formats and the different transmission formats have different transmission properties. The two transmission formats can differ with respect to the transmission rates thereof. In this way, it is possible both to select an appropriate transmission, which corresponds to an established standard transmission format, in order to achieve as high a compatibility as possible for the control units and operating devices of a lighting system, and to select a modified transmission having a second transmission format, said transmission being adapted to the special requirements of the lighting system, and use it for transmitting control commands.

Description

Method for controlling an operating device for lamps, in particular LED

The invention relates to a method for controlling at least one operating device for lighting means, in particular LED, according to the preamble of patent claim 1, a lighting system with a control device and at least one operating device for operating light sources, in particular LED, according to the preamble of claim 12, an operating device for operating light-emitting means, in particular LED, with an interface circuit for receiving digital control commands via a bus line and a converter for operating the light-emitting means according to the preamble of patent claim 17 and a control device for a

Lighting system with at least one operating device for operating light sources, in particular LED, according to the preamble of claim 23.

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. With the term

Lamps are both gas discharge lamps as well as halogen lamps or light emitting diodes (LED) called. Such a light source can individually or together with be arranged further bulbs in a luminaire, which may also contain the operating device.

State of the art

In modern lighting systems digital control commands are often sent to the operating devices by the central control unit. In particular, brightness values can be predetermined by these external control commands in order to achieve different illumination states. The operating devices may be provided with an address in order to enable a single or group-wide control by the central control unit.

A widely used control method is the control of lighting systems according to the DALI (Digital Addressable Lighting Interface) standard. This standard defines an interface and a transmission format for the digital control of operating devices, whereby addresses can be assigned for the individual operating devices. The operating devices can be switched on and off via the external control commands or controlled in the brightness, in addition, a special operating condition such as an emergency lighting state can be initiated and error messages are queried.

The DALI standard is 16 bit Manchester code, which allows a maximum dimming speed with a brightness change from 1% to 100% in just 0.7 seconds. , The high level is in the region of about 16V, the low level at a voltage of about 0 volts. Control according to the DALI standard limits the number of possible addresses within a lighting system to a defined value (65 addresses for one area). This number is especially for

Lighting systems with bulbs of different colors often insufficient. Therefore, in today's lighting systems with a higher need for addresses, a subdivision of the lighting system is made to multiple subsystems, but this division requires an increased number of control devices and thus increases both the expense of installing such a lighting system and the complexity of the control devices that are used in In this case, control and monitor a multi-stage lighting system.

Through the use of new light sources such as light emitting diodes there are many possible applications of lighting systems, in particular a mixing of colors and a change in the color of the lighting system can be made possible. Through the use of different colored bulbs can be realized by means of such control method color changes. In such a colored lighting, the light of the different colored bulbs can be coupled and mixed with the help of a corresponding optics. The mixture of different colored light can be done in particular in 'a lamp or by the combination of several lights. Such color changes may require adjusting the rate of brightness change. The published patent application DE 10 2006 001 256 A1 describes. a method for adjusting the brightness of a luminous means in dependence on brightness commands. According to this method, the operating device monitors the time sequence of the brightness commands and adjusts the speed of the brightness change, which was initiated by means of a control command, to this time sequence. - For the viewer, a brightness change can be well perceived, especially at low levels of brightness. In particular, in the case of slow changes in brightness, it is therefore very important that this takes place continuously and with a very small step size of brightness levels. The viewer can step by step

Brightness change as unpleasant. In particular, in the use of different colored bulbs to change the color of the lighting system or the lamp can already be perceived by the viewer a very small change in color.

According to the DALI standard, only a limited number of brightness levels are available based on the given brightness settings for brightness adjustment. This limited number of

Brightness levels, especially in color change applications, limit the brightness range and the speed that can be used for brightness changes.

According to DE 10 2006 001 256 A1, although a better adaptation of the speed of the desired brightness change can be achieved, this method only makes it possible to increase the speed but no increase in the number of brightness levels is possible. Furthermore, according to DE 10 2006 001 256 A1, an existing transmission format is used to transmit the control commands. By using the existing transmission format, the maximum transmission rate and thus also the maximum speed for brightness changes is limited and bound to the available transmission format.

Today's lighting systems require the use of a widely used standard as a method of controlling the lighting system and the operating devices contained therein. A change or adaptation of such a standardized method means a great effort in the implementation by the user. It must adapt their respective products to the agreed standard and be trained on the appropriate standard and the customers, especially the lighting manufacturer and install such lighting systems and operate the experts, both the manufacturer of the respective operating devices and the ^{'manufacturer} of the control units and comply with the relevant requirements.

Presentation of the invention

It is the object of the invention to provide a method which the control of operating devices by a control unit without the above mentioned disadvantages or under a significant ■ reduction of these disadvantages.

This object is achieved for a method according to the invention by the characterizing features of claim 1 and for a generic device according to the invention by the characterizing features of claims 12, 17 and 23. Particularly advantageous embodiments of the invention are described in the subclaims.

The inventive solution for controlling operating devices is based on the idea that selectively a first transmission of control commands according to a defined standard transmission format or by the choice of the user one of this first

Transmission format deviating second transmission format can be used. Both transmissions are carried out by means of digital control commands, which are sent from one or more central control units to at least one operating device.

In this way it is possible to have both one

Transmission, the one established

Standard transmission format corresponds to, to ensure the highest possible compatibility for the control units and

Operating equipment of a lighting system, as well as ^' to special requirements of the

Illuminated system adapted modified transmission with a second transmission format and to use for the transmission of control commands.

Advantageously, the transmission rates of the two transmissions differ from one another. Thus, for the application case of a required high speed for brightness changes for the second transmission, a higher transmission rate can be selected than is permitted for the first transmission according to the established standard. Advantageously, the transmission formats may differ in the edge steepness of their signals, in the level level or even in the number of bits of the signals.

The second, freely selectable transmission can also be characterized by additional control commands, which can provide further options for the control of the operating devices. Due to these additional control commands, for example, a larger number of addresses or a larger number of brightness levels can be realized by means of such a transmission with an additional transmission format.

A control command according to the invention is not just an ON command, OFF command or newer

Brightness value that can be transmitted to an operating device, but may also contain advanced information. In particular, a color information or a color command, an address, a state information or an error signal can be transmitted as a control command.

According to the present invention, the user at the control unit can stop the transmission. He can choose the transmission according to an established standard or specify a second transmission. An advantageous application of a freely selectable transmission results from the scaling of the transmission rate of the first transmission. Preferably, a multiplication of set first transmission rate, in particular a doubling or tripling the transmission rate ^' can be selected by the user.

Such a transmission by multiplying the first transmission rate can be advantageously selected by a special control command. This control command can be sent both to the connected control units and to the operating devices. Upon receipt of this special control command, the controllers and / or the operating devices change their transmission in accordance with the control command.

An alternative solution is that at least one control device, the transmission to be selected by the user or another specification can be specified. The other participants of the lighting system on the basis of the detected transmission adaptive their transmission for receiving and sending control commands. As subscribers, other devices connected to the bus line or control devices are referred to in the further description. Preferably, the transmission is analyzed by the other participants of the lighting system after the start of a transmission of control commands.

The invention also relates to a lighting system with a control device and at least one operating device for operating light sources, wherein the control device can send digital control commands to at least two different transmission formats.

The invention also relates to a device for receiving control commands by an operating device of Lamps. The operating device has a driver circuit for operating the luminous means. For receiving and evaluating the control commands, the operating device has an interface circuit. In accordance with the received control commands, the operating device can control the operation and the brightness of the lighting device via the driver circuit.

According to a particularly preferred embodiment, the operating device can monitor the transmission via its interface circuit and analyze the transmission based on the received control commands. According to the detected transmission, the operating device can adapt its interface circuit to this transmission. The detection of the transmission can advantageously take place on the basis of the evaluation of the transmission rate of the received control commands.

According to a further preferred exemplary embodiment, a control device for an illumination system can also receive digital control commands according to at least two different transmission formats, wherein the control device can independently recognize on the basis of the received digital control commands, according to which transmission format the control commands are sent.

Description of the preferred embodiments

The invention will be explained in more detail with reference to the accompanying drawings. Show it: Fig. 1 shows schematically the embodiment of an operating device according to the invention for an LED as a light source

^'Fig. 2 schematically shows the configuration of a

Lighting system with a control device according to the invention and an operating device according to the invention for a gas discharge lamp as a light source

3 is a schematic timing diagram for explaining the transmission of control commands according to the invention

The invention will be explained with reference to an embodiment of an operating device for an LED. However, the present invention can be applied to all types of lighting apparatus. The use of very different bulbs is possible, it can be used in particular gas discharge lamps, halogen lamps or inorganic or organic light-emitting diodes.

In the operating device 1 shown in Fig. 1, as a central component, a control circuit 2, which controls and monitors all functions of the components of the operating device 1. In particular, the operation of the converter 3 is controlled and. monitored, in particular also regulated. The converter 3 is connected via connections to the power supply network 20 and receives the energy required to operate the lamp.

Furthermore, it also controls the operation of the lamp, in particular the brightness of the lamp. As a light source is a lamp LED to the converter 3 of the Operating unit 1 connected. The converter 3 assumes both the task of correct power consumption from the power supply network 20, which may be predetermined by the provisions of the energy supplier. Above all, this task can involve a sinusoidal current consumption with as few high-frequency disturbances as possible. Of the . Converter 3 may therefore include a so-called filter for avoiding high-frequency noise, which may either come from the power supply network 20 or generated by the converter 3, as well as an active power factor correction circuit. In addition, the converter 3 ensures the proper operation of the lamp LED. In particular, he can adjust the current and / or voltage ^• through the lamp LED or regulate. In a particular embodiment, the

Converter 3 also designed as a multi-stage converter, 'to divide' the various tasks of the individual stages of the converter 3. 'Advantageously, is ensured by a stage, the correct current consumption from the power supply network 20, a subsequent stage ^■ controls the operation of the lamp LED. The power grid 20 may be a low frequency AC voltage with a voltage of 230V or a DC voltage of 24V. Depending on the type of power supply network 20, the

Converter 3 may be designed as a DC-DC converter or AC-DC converter. In a particularly advantageous embodiment, the converter 3 may include an energy store (Cbus), which may be formed by a storage capacitor or a rechargeable battery. The operating device 1 and the control unit 10 are part of a lighting system A.

The control circuit 2 is further connected to the interface circuit 4. The

Interface circuit 4 is connected to the bus line 21. Via the bus line 21, the control commands sent by the control unit 10 are transmitted. These control commands are received by the interface circuit 4 and forwarded to the control circuit 2. The control circuit 2 can evaluate and store the control commands. According to the transmitted control commands, the control circuit 2 can control the operation of the lamp LED by the converter 3. The control circuit 2 can also monitor the operation of the lamp LED and the converter 3 and s.enden in the event of a fault or special event of this ^' detection and via the interface circuit 4 and the bus line 21 a corresponding control command to the control unit 10 s.enden. In addition, further control devices 11 may be connected to the bus line 21 '. The various control devices 10 and 11 may be different sensors such as motion or brightness sensors, but also actuators controllable by a user, such as switches, buttons or touch-sensitive screens with a user interface for lighting control.

The control circuit 2 may include a memory 8 or drive an external memory 8, which is present in the operating device 1.

The bus line 21 is formed as a two-wire data line, which as a control command with a digital signal a low DC voltage transmits. For example, a data transmission according to the DALI standard is transmitted via the bus line 21. The

Interface circuit 4 and controller 10 are capable of receiving control commands in accordance with the DALI standard. However, according to the invention, it ^is' possible to alternatively select to the data transmission according to the standardized transmission a transmission with different parameters. Due to the ability to transfer data according to DALI standard of both the

Operating device 1 and the control unit 10, a very high compatibility for the components of the lighting system can be achieved. As a result, the user has a large number of different control and operating devices from different suppliers and for different applications available, which can be selected as needed by the user for a corresponding lighting system.

According to the invention, via the bus line 21, a further transmission mode deviating from the DALI standard can be transmitted.

For example, the transmission rate for the control commands can be increased or decreased many times, ideally the transmission rate is doubled or tripled. Alternatively or additionally, the edge steepness of the transmitted signals can be increased or reduced by a multiple, ideally the slope is doubled or tripled. As a further possibility of changing the transmission, the amplitude of the signals to be transmitted can be changed in a similar manner. It should be noted that the data transmission of the control commands via the bus line 21 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 power grid 20. For the mentioned

Transmission variants exist in each case standardized transmission methods analogous to the DALI standard for wired data transmission, wherein according to the inventive method, a modified data transmission via the same bus line 21 can take place.

The change can be specified by the user to the control unit 10. The user can specify the control unit via a command, for example, the factor of changing the transmission rate. This command represents a special control command. The control unit then adapts its transmission rate with which it transmits the control commands to the bus line 21 in accordance with the user command. In the same way, for example, the slope or the amplitude of the transmission can be adjusted. Before that. Control unit 10 adapts its transmission, it can inform by a special control command via the bus line 21, the other control units 11 and the connected equipment over the change of transmission. The other control devices 11 and the connected operating devices 1 are hereinafter also referred to as bus subscribers'. In an alternative variant, the controller 10 can adjust its transmission rate according to the specification for the transmission to be selected and after adjustment of the transmission rate at a first control by a user or a first activation of an existing sensor, the control commands with the adjusted transmission rate via the bus line 21 transmit the further bus subscribers. These bus participants monitor the bus line and analyze the transmission rate of the bus

10 received control commands. Based on the transmission rate, the other bus users can also adjust their transmission rate. Furthermore, both the receipt of the control commands and the transmission of control commands to the determined transmission rate

15 be adapted. It is particularly advantageous if the changed transmission rate is a multiple of the first, standardized transmission rate. In this case, the bus subscribers based on the measured transmission rate from one in the

20 control circuit 2 stored reference table the the

Select measured values corresponding predefined transmission rate and adjust their transmission so. Such a reference table can be stored in the memory 8 which is present in the operating device 1. about

25. Special control commands of the control unit 10 can this

Reference table can be adapted or extended. By limiting the possible transmission rates to a multiple of the first (standardized) transmission rate, the risk that may arise due to deviations in the

30- transmission rate errors during transmission occur, can be reduced. Such a deviation in the transmission rate can be due to component tolerances or temperature fluctuations, which have an influence on the Components of the interface circuit 4 may have, be caused. By fixing the possible transmission rates to a multiple of the first (standardized) transmission rate combined with the storage of predefined transmission rates, the

Risk of error for the transmission are greatly reduced.

In the case of this embodiment, ^"reads the control circuit 2, the control commands which are transmitted from the controller 10 via the bus line 21, from the interface circuit 4 from. In this case, the control circuit 2, the received control commands in the memory 8 cache and analyze based on their transmission rate. The transmission rate is defined by the bit length of the individual components of the control commands.

An example of such a transmission will be explained later with reference to FIG. The control circuit 2 analyzes the control commands and can then adjust the transmission rate for control commands to be received or sent later.

Alternatively, the control unit 10 can automatically calculate the optimum transmission rate on the basis of the desired maximum speed for the change in brightness, which can be preset by the user by programming the sequence of the different brightness values or other illumination parameters. As a result, an optimal compromise between the required speed for the change in brightness and the maximum permissible transmission rate for secure data transmission can be achieved. By adjusting the transmission rate, the lighting system can be better adapted to specific user requirements. ^' Thus, for example, by a multiplication of

Transmission rate to achieve a faster brightness change by a 'faster sequence of control commands to change the brightness'. • •

Alternatively, by increasing the transmission rate, a higher number of brightness levels or a higher number of addresses can be achieved. For example, in combination with the increase in the transmission rate, the data length of the control commands to be transmitted can also be increased.

For example, instead of the 2-byte control commands of the standard protocol, a 3-byte control command or even a 4-byte control command can be sent for addressing. In this way, with a doubling of the transmission rate and a

Doubling the data length in the same time a much larger amount of data and thus a much larger address range are addressed.

After changing its data transmission, the control unit 10 can carry out a check in order to check whether the further bus subscribers, such as, for example, the operating unit 1, can record the adapted data transmission and adapt their data transmission to it. For this purpose, the control unit 10 can send a control command for status query to the individual bus subscribers. If the individual bus users can adapt their data transmission, they will send back a status feedback control command according to the customized data transfer. If there is no status feedback, the control unit 10 must assume that the addressed bus subscriber (s) are not capable of adapting the data transmission. In this case, the controller 10 must reset its data transfer back to the first data transfer. According to this example, the controller could. 10 on the basis of the known addresses (these have been awarded in the lighting system at startup) query each individual bus subscriber such as the operating device 1 and check whether the adapted data transmission can be used.

If. the control circuit 2 in the operating device-1 on the basis of the changed transmission determines that the transmission format has been changed to transmit the digital control commands, or if the transmission format for transmitting the digital control commands by means of a. changed special control command, the control circuit 2 can store in the memory 8 information about the last selected transmission format for transmitting the digital control commands. This storage of information can also be done at regular intervals or after every first receipt of a control command after 'switching on the operating device by switching on the power supply.

The example shown in FIG. 1 can be extended to the effect that three operating devices Ia, Ib and Ic, each with a differently colored LED (for example red, green and blue), are controlled via a control unit 10. The three operating devices Ia, Ib and. Ic, each with a different color LED (for example, red, green and blue) are combined in a lamp to achieve a color illumination. Alternatively, however, a plurality of converters 3a, 3b and 3c may also be present in an operating device 1, each controlling at least one LED of one color (for example red, green and blue). The control of the three converters 3a, 3b and 3c is performed by the common control circuit. 2

If the user now desires a special effect lighting with fast and gentle color changes, which is only very limited feasible due to the limitation of data transfer according to DALI standard, he can set a higher transfer rate and a higher brightness gradation directly or through the calculation in the control unit 10. Then the data transmission via the bus line 21 is adapted by the control unit 10.

FIG. 2 shows an example in which at least one control unit 10 has an operating device 1 'for a gas discharge lamp LA as lighting means via a

Bus line 21 drives. ^■ At this bus line 21 a further control device 11 is connected.

The operating device 1 'has a rectifier 14, which is connected to the power supply network 20. The power absorbed by the rectifier 14 is transmitted to a DC link circuit 15, which is an active power factor correction circuit (PFC) and a Can contain energy storage. On the

DC link circuit 15 is followed by an inverter 16, which controls the gas discharge lamp LA via a load circuit 17. The inverter 16 can be formed by a half-bridge, which feeds the load circuit 17 with a clocked DC voltage. The load circuit 17 may by a series resonant circuit of a. Inductance and a capacity are formed.

The control circuit 2 is connected via the interface circuit 4 to the bus line 21 and can thus receive the commands sent by the ^' control unit 10 control commands.

The control unit 11 can monitor and analyze the data transmission via the bus line 21. If it detects a change .der transmission rate by the controller 10, it can also adjust its transmission rate for the control commands to be sent and received. In the same way, the operating device 1 'can adjust its transmission rate for the control commands to be sent and received.

Fig. 3 shows a timing diagram and is intended to illustrate the transmission of control commands according to the invention. Shown here is a signal A according to the DALI standard, which has a defined transmission rate. The length of a control command is fixed, as well as the amplitude and slope of the signal. A control command according to DALI standard consists of 16 bits, whereby the

User data transfer rate is 1200 bits per second. The bit length is 416us. This so-called bit length determines the transmission rate with which the control commands be transmitted. The allowable edge steepness is in the range of 10us up to 100us.

Furthermore, a second signal B is shown, which has twice the transmission rate of the signal A 5. The slope of this signal can be in the range of 5us to 30us. For example, the bit length can be reduced to 213us, but it can also be reduced to a range of 100us to 150us.

10

The second signal B may also differ from the signal A in the edge steepness of its signals, in the level level or even in the number of bits of the signals.

Ϊ5

The two different transmission formats may also differ in their transmission in that the first transmission format uses a so-called 'active low' transmission, i. it is permanently a level

20, for example 12V, as long as no data is transmitted. In the case of data transmission, the level for transmitting a bit is pulled to a level below 2V, for example. The second transmission format, on the other hand, can be a signal with a so-called, Active High '

25 use transmission. In this case would be permanent

Levels of, for example, OV are present as long as no data is being transmitted. In the case of data transmission, the level for transmitting a bit is increased to, for example, 12V.

30 In this way, the choice is made between a data transmission in which a permanent voltage is applied to the bus line 21 through the 'active low' transmission and thus a supply of control devices 10 via the bus line 21 is possible, and one

Data transmission with an 'Active High' transmission possible. The 'Active High' transmission has the advantage that no permanent power to the bus line 21 is required and thus the control units 10 can be completely switched off in the absence of bus activity.

Claims

Claims :

1. A method for driving an operating device (1) for Leuchtmittel-, in particular LED, characterized in that the operating device can receive digital control commands for at least two ^• different transmission formats.

2. The method according to claim 1, characterized in that the different transmission formats have different transmission properties.

3. The method according to claim 1 or 2, characterized in that the operating device (1) can also send digital control commands for ^■ at least two different transmission formats.

4. Method according to one. of claims 1 to 3, characterized in that the two transmission formats differ by their transmission rate.

5. The method according to any one of claims 1 to 4, characterized in that the first transmission format corresponds to a standard transmission format.

6. The method according to claim 5, characterized in that the first transmission format corresponds to the DALI standard.

7. Method according to one of the claims! to 6, characterized in that the operating device (.1) independently recognizes on the basis of the received digital control commands, according to which transmission format the control commands are sent.

8. The method according to claim 7, characterized in that the operating device (1) independently recognizes on the basis of the bit length of the received digital control commands, according to which transmission format the digital control commands are sent.

9. The method according to any one of claims 1 to 6, characterized in that the operating device (1) receives information based on a special control command, according to which transmission format the digital control commands are sent.

10. The method according to any one of claims 1 to 9, characterized in that the digital control commands can cause a change in the brightness of the light source with which the operating device (1) drives the light source.

11. The method according to any one of claims 1 to 10, characterized in that the operating device (1) due to the transmission format used at different speeds ^' can change the brightness of the lamp.

12. lighting system (A) with a control unit (10) and at least one operating device (1) for operating light sources, in particular LED, characterized in that the control unit (10) can send digital control commands to at least two different transmission formats.

13. Illumination system (A) according to claim 12, characterized in that the different transmission formats have different transmission properties.

14. Illumination system (A) according to claim 12, characterized in that the two transmission formats differ by their transmission rate.

15. Illumination system (A) according to claim 12 or 13, characterized in that the first transmission format corresponds to a standard transmission format.

16. Illumination system (A) according to claim 12 or 13, characterized in that the control unit (10) can send out a control command for status query according to the second transmission format and in the absence of feedback of the addressed operating devices (1) resets the transmission back to the first transmission format.

17. operating device (1) for operating light sources, in particular LED, with terminals for a current consumption from the

Power supply network (20), an interface circuit (2) for receiving digital control commands via a bus line (21), a converter (3) for operating the lighting means, a control circuit (2) according to the

Interface circuit (2) received digital

Control commands the converter (3) controls, characterized in that the operating device (1) can receive digital control commands for at least two different transmission formats.

18. operating device (1) according to claim 17, characterized in that the different transmission formats have different transmission properties.

19. Operating device (1) according to claim 17 or 18, characterized in that the operating device (1) independently recognizes on the basis of the received digital control commands, according to which

Transmission format the control commands are sent.

20. Operating device (1) according to claims 17 to 19, characterized in that the operating device (1) receives information based on a special control command, according to which transmission format the digital control commands are sent.

21. Operating device (1) according to claims 17 to 20, characterized in that the operating device (1) has a memory (8), and the operating device (1) in this memory (8) can store information, which transmission format last for the transmission of the digital control commands was used.

22. Operating device (1) according to claims 17 to 21, characterized in that the operating device (1) contains a plurality of converters (3a, 3b, 3c) to control different colored LEDs.

23. Control unit (10) for a lighting system with at least one operating device (1) for operating light sources, in particular LED, wherein the control unit (10) can receive digital control commands for at least two different transmission formats, characterized in that the control unit (10) based the received digital control commands automatically recognizes the transmission format to which the control commands are sent.

24. Control unit (10) according to claim 23, characterized in that the control unit (10) can also send digital control commands center, ls of the detected transmission format.