AT14360U1 - Method for addressing illuminant devices - Google Patents

Abstract

Lighting system for controlling at least one light source, comprising at least one operating device for operating the light source, wherein the operating device has a first interface and this interface is connected to a control device and to other operating devices, wherein the operating device according to the control signals received via the first interface Illuminant operates, the operating device at least one further interface for connecting a sensor, in particular a brightness sensor comprises, a configuration element which is connected to the further interface of an operating device and which transmits configuration information to the operating device, wherein the configuration information includes address information and the configuration element generates the address information due to an approach of a permanent magnet.

Description

description

METHOD FOR ADDRESSING LIGHT SOURCE OPERATING DEVICES

The invention relates to a method for controlling lighting device according to the preamble of claim 1. In addition, the present invention relates to a lighting system for controlling at least two lamps according to the preamble of claim 2 or 17th

TECHNICAL FIELD AND PRIOR ART

Light control and light management systems have become established as an integral part of modern lighting solutions. Light source operating devices of modern design, such as electronic ballasts for gas discharge lamps or operating devices for light-emitting diodes usually have interfaces via which external control commands can be transmitted to the operating device. For example, a desired luminous intensity (dimming level) of the luminous means can be set by appropriate control signals.

In the lighting industry, various standards have been developed for the control of light bulbs that differ in complexity. The most technologically advanced are digital solutions, where the light source operating device has a digital interface, can be sent via the digital control commands from a control unit to the light bulb operating device. The communication can be bidirectional, i. E. The light bulb operation device can not only be a receiver of signal commands, but also act as a transmitter of signals. For example, the illuminant device may actively report a status report back to the controller when an error occurs.

For the transmission of signals from the prior art a variety of ways are known: So is wired transmission (for example, by using the power supply line (Powerline) or use of a separate line from the power supply line) and wireless transmission (eg radio, infrared) possible.

As an example of the control of lighting equipment is referred to the so-called DSI technology (Digital Serial Interface) and the so-called DALI protocol (digital adressab-le lighting interface). The DALI standard provides a comprehensive set of digital control commands for communication with the lamp operating device. In a DALI-compliant lighting system, an associated bus device, including a digital control unit, is necessary in addition to the illuminant operating device with a digital interface.

In many cases, the user desires a less expensive technology that is a bit cheaper, but nonetheless provides the essential functionality. Thus, from the prior art operating devices are known in which at the digital interface (control input) either a digital signal or a signal generated by means of a power supply supplied with a button signal can be applied.

If the user does not want to use the digital peripherals, then optionally the digital control input of the operating device can be controlled by means of a button operation.

In this case, for example, the time duration and the repetition rate of the button operation is evaluated as a signal for switching on and / or off or for brightness control (dimming). An example of such an operating device, to whose digital control input a signal generated by means of a mains voltage supplied with a button or switch rests, is disclosed for example in DE 297 24 657.

The definition of a dimming scenario with suitable values for the dimming levels, fade-on and fade-off times proves to be not easy in practice, since the switching behavior of the

Operating device can strongly depend on the specific application. For example, in hospital corridors it is prescribed by standards that a certain amount of residual brightness always has to be present even at night, even if no movement has been detected for a certain period of time. On the other hand, in a staircase of a private residential complex at night, the lighting can be switched off relatively quickly, after 'rest' has returned. The temporal frequency with which a motion detection occurs, and the time between two consecutive motion detections can vary widely: The motion detector in an underground car park speaks in 'rush hours' very often when the underground car park is heavily frequented (for example, in the morning at work and evening at the end of work ), while in quieter times, for example in the low hours of the night, a movement signal is relatively rarely triggered.

Operating devices of the prior art have only a dimming scenario, the determination of the dimming scenario with the individual dimming parameters takes place during the manufacture of the operating device or during installation shortly before commissioning, for example by means of programming, and can be in operation not be changed.

When setting the dimming scenario, two aspects should now primarily be considered: Firstly, in order to save as much energy as possible, the bulbs should be as short as possible and only if they are really necessary in operation. On the other hand, rapidly successive switching on and off operations with a short turn-on and turn-off time are to be avoided, since this can have a life-shortening effect on the lighting means.

PRESENTATION OF THE INVENTION

The object of the invention is to improve the control of Leuchtmittelbetriebsgeräten. In particular, the requirements of energy efficiency and conservation of the light source should be taken into account.

The said object of the invention is solved by the features of the independent claims. The dependent claims further form the central idea in a particularly advantageous manner.

According to the invention, a method for controlling electronically controlled illuminant devices is proposed. This method is used to control at least one light source, wherein the light source is operated by an operating device, the operating devices via a first interface with a controller and optionally connected to other operating devices, wherein the operating device according to the control interface received via the first control signals operates the light source in that the operating device has at least one further interface for connecting a sensor, in particular a brightness sensor, a configuration element which is connected to the further interface of an operating device and which transmits configuration information to the operating device, wherein the configuration information includes address information and the configuration element contains the address information generated due to an approximation of a permanent magnet.

Typical examples of such a light source operating device are electronic ballasts (ECG) for gas discharge lamps or operating devices for organic or inorganic light-emitting diodes.

The invention also relates to a control device for lighting means, which is designed for carrying out such a method. Further advantages, features and characteristics of the present invention will now be explained with reference to the two appended drawings.

Figure 1 shows an arrangement of a light source operating device with a motion detector.

Figure 1 shows a schematic representation of a lighting system 10 comprising a known motion detector 1, an electronic light source operating device 2, and a connected to an output 3 bulbs 4. For bulbs 4 may be in principle to any bulbs, such as gas discharge lamps or organic or inorganic light-emitting diodes. The illustrated lamp operating device 2 has 3 terminals PE, L, N, which can be contacted with the ground, the phase conductor and the neutral conductor. The operating device 2 also has a first interface with the terminals D1 and D2.

This can be designed so that via these connections to the operating device digital commands, for example. In accordance with the DALI standard protocol can be transmitted or the operating device can send signals. In this case, the operating device can be connected via the first interface with a DALI control unit. Optionally, the two terminals D1 and D2 may be formed so that signals are transmitted by the supply voltage such as the mains voltage or push button signals.

In the illustrated example, the terminal D1 is connected to the neutral N of the power supply 5. Between the other terminal D2 of the operating device 2 and the phase conductor L of the power supply 5, a commercially available motion detector 1 is connected.

At the control input D2 can now essentially two different signals anlie gene, namely one for the detection of movement by the motion detector 1 and a different signal for the case that no movement on the motion detector 1 detek-is animal. In the example shown, the following definition is present: If the motion detector 1 detects a movement, it closes the connection between the phase conductor L and the connection D2 briefly so that the signal level of the phase conductor L is present at the control input D2. In the other case, when the motion detector 1 detects no movement, the connection between the phase conductor L and the terminal D2 is interrupted, so that no voltage is applied to the terminal D2. Of course, other definitions or encodings of the motion signal are possible.

For the evaluation and optimal use of the received via the first interface control signals, it is advantageous if each operating device, an address can be assigned. Several control gear can also have the same address and thus be grouped together.

The operating device 2 also has a further interface with the terminals D3 and D4. At this further interface, for example, a brightness sensor or other sensor or even a signal from another operating device or control unit can be received. It may also be possible that signals can be sent via this further interface. The respective use or usage of this additional interface can be programmable.

Now, a configuration element can be connected to this further interface, which transmits configuration information to the operating device, wherein the configuration information includes address information and the configuration element generates the address information due to an approach of a permanent magnet.

For example, for the purpose of addressing the operating devices, a user can address the individual operating devices by successively holding a permanent magnet in the vicinity of the operating devices. The operating devices can recognize such a spatial approach of a permanent magnet by means of the configuration element. For this purpose, the configuration element can have, for example, a magnetic field sensor which can detect a change in the magnetic field around the configuration element and, due to such a change, close to an approximation of a permanent magnet and can thus recognize it.

The configuration element may comprise a memory, which is preferably non-volatile and can be described several times.

Via the further interface a unidirectional or bidirectional communication between the operating device and the configuration element are made possible.

The operating device can be placed in an addressing mode via the first interface. The configuration element may have means for detecting a proximity of a permanent magnet and the operating device may receive the address information from the configuration element when the operating device has been placed in the addressing mode and the configuration element detects an approach of a permanent magnet.

The configuration element may have means for detecting an approach of a permanent magnet n and the operating device may receive the address information from the configuration element. In this case, the evaluation element can, in evaluation of the recognition of an approach of a permanent magnet, either transmit the address information directly to the operating device or generate it itself if the operating device has been set to the addressing mode. The configuration element may comprise means for evaluating radio signals. The variant in which the configuration element receives the assignment of an address directly via the radio signal (ie encoded as a data record by means of the radio signal transmission) and further transmits the address information directly to the operating device in evaluation of the radio signals offers, for example, for use in systems without a return channel to the Control unit (ie in a unidirectional execution of the first interface such as in a digital broadcast control such as DSI or a button control) an advantageous way of address assignment.

The configuration element may comprise means for detecting an approach of a permanent magnet and that the operating device receive the address information from the configuration element. Furthermore, the configuration element can set the operating device in an addressing mode, and if the operating device has been placed in the addressing mode, in evaluation of the detection of an approach of a permanent magnet, the address information either transferred directly to the operating device or self-generate.

Optionally, the configuration element can also receive a radio signal or even send out radio signals, for example to confirm receipt of a radio signal. Thus, for example, the receipt of a transmitted address or the assignment of an address can be confirmed. Thus, a bidirectional data transmission via radio signals between the configuration element and the remote control can be done.

The configuration element can additionally receive control information via the radio signal, and change the operation of the light source according to the newly acquired configuration information depending on these control information.

The radio signals can be transmitted by means of a standardized transmission such as WLAN, Bluetooth, Zigbee, GPRS or UMTS. The radio signals can be transmitted by a remote control. Such a hand-held transmitter can be designed as a programming device with radio transmission for the address assignment or can also be formed by a normal mobile radio device such as a mobile phone, which has the option of transmission with WLAN, Bluetooth, Zigbee, GPRS or UMTS.

The lighting means may be an organic or inorganic LED or a gas discharge lamp (fluorescent lamp, high-pressure gas discharge lamp).

When exchanging an operating device, the address information as well as optionally certain operating data can be transmitted via the configuration element of the exchanged to the newly inserted operating device.

Over the further interface, a power supply of the configuration element can be done by the operating device.

In addition to the configuration element, a sensor can additionally be connected to the further interface.

The configuration element can also be connected instead of a sensor to the other interface.

The configuration element can be marked in color.

The operation of the luminous means by the operating device can additionally take place depending on a predetermined by the configuration element configuration information.

The configuration element can be connected to the additional interface in addition to a sensor or instead of a sensor.

The radio signal can also be generated by means of a remote control, so that a passive and thus cost-effective receiver in the configuration element is sufficient.

The hand-held transmitter can generate a radio signal as a highly oriented radio lobe in order to address as few operating devices in the room. Furthermore, this remote control can have a WLAN or cellular connection with a DALI control unit (eg arranged in a control cabinet).

In order to address the operating devices accordingly, the DALI control unit can set the operating devices in an addressing mode and then the DALI control unit can poll all operating devices continuously or repeatedly. Now, if the technician directs the permanent magnet in the vicinity of a luminaire with operating device, a magnetic field is radiated by the permanent magnet and slowly amplified.

As soon as a configuration element recognizes this magnetic field as a receiver, in particular an approximation of the permanent magnet by the amplification of the magnetic field, this information is forwarded from the configuration element to the operating device and from the operating device via the first interface to the DALI control unit. Additionally or alternatively, the operating device can change the brightness of the light source. Thus, the lamp or the operating device is identified and the operating device can be assigned an address, which is also known to the DALI control unit. Thus, an address can be assigned by means of a permanent magnet each operating device.

In addition to the addressing, the operating device can also change the operation of the lighting device according to a configuration information predetermined by the configuration element.

[0047] For example, the following changes are possible: [0048] change of the brightness value in emergency light operation [0049] lock or unlock the dimming operation in emergency light operation change of controller parameters for the light bulb operation (rated current, heating power) [0051] change the behavior when connecting sensors to one of the interfaces - change or extension of the control signals (instruction set) - Renewal (update) of the control software (firmware) of the operating device or at least the interface control of the operating device [0054] - Change shutdown thresholds or fault detection thresholds (eg for the

Illuminant operation, an interface or the supply). - Change of dimming scenarios with suitable values for the dimming stages, fade-on and fade-off times. [0056] Change of individual values for dimming stages, fade- on and fade-off times - Change in the sequence behavior (eg shortening of the preheating time or skipping of the preheating time, shortening of the ignition phase) The operating device can also change its functionality on the basis of the newly acquired configuration information.

For example, a change of controller parameters for the lighting means mean that the lamp type to be operated is changed or that changed operating data for the already connected lamp type can be specified. Thus, for example, the rated current or the heating power (this may affect the heating current and / or the heating voltage) change. However, a change in the control parameters can also mean, for example, that limit values or the feedback control behavior are adapted for a temperature limitation. The change in the heating power in the preheating can be done, for example, by changing the preheating time (while maintaining the transmitted heat output in a specific time window). However, an adaptation of control parameters or the sequence behavior can also mean increased compatibility with other installed operating devices.

For example, a new operating device can thus be used in the event of a defect, which actually enables more efficient preheating with a shorter preheating time. However, in order to enable a uniform and simultaneous start of all operating devices, the new operating device can be assigned a longer preheating time via the configuration element, which corresponds to the preheating time of the already installed operating devices.

The configuration element can also allow the user, for example a lighting manufacturer, greater flexibility, for example during test measurements. Due to the possible change in the flow behavior or the change of shutdown thresholds or fault detection thresholds, a faster sequence of test measurements or even a simpler test measurement setup, for example using a substitute load instead of the actual illuminant, can be made possible.

The configuration element can also have a plurality of DIP switches or jumpers for setting configuration information. In this case, for example, the configuration element can either read out the corresponding configuration information from its memory in accordance with the selected switch settings of the DIP switches and transmit it to the operating device, or else the operating device can directly read out the selected switch positions (these could, for example, be looped through).

It may also be possible to read data (operating data) from the operating device via the configuration element, in order to then change it and transfer it back to the operating device in a modified form. This can be done for example via a programming device, which can read the memory of the configuration element and change or rewrite. In this way, a user can make a change to an operating device without the operating device must be removed or a programming device must be connected directly to the operating device. In addition, the configuration element can also be permanently connected to the operating device.

The configuration element may for example be designed as a plug or socket, which can simultaneously achieve a mechanically stable connection to the operating device (in particular the housing of the operating device) and a reliable contact with the other interface of the operating device. The configuration element can also have a connection for a computer interface, for example a USB connection, a Firewire connection or an eSATA connection. If such a connection for a computer interface is present, the configuration element can be easily connected by the user to a computer and there stored data (operating data) can be read from the configuration element, be changed or transferred from the computer to the configuration element. Thus, a simple readout and / or predetermining data for the configuration element via a computer can be made possible.

Thus, a method for controlling at least one lighting means is also possible, wherein the lighting means is operated by an operating device, the operating device is connected via a first interface with a control device and with other operating devices, wherein the operating device according to the over the first interface received control signals, the lighting means operates, the operating device at least one further interface for connecting a sensor, in particular a brightness sensor comprises, a configuration element which is connected to the further interface of an operating device and which transmits configuration information to the operating device, wherein the configuration information includes address information and the configuration element generates the address information due to an approach of a permanent magnet.

It is thus also possible to have a lighting system comprising at least one operating device for operating the lighting device, wherein the operating device has a first interface and this interface is connected to a control device and optionally to other operating devices, the operating device corresponding to the one via the first Interface receiving control signals operates the light source, the operating device is connected to a configuration element that transmits configuration information to the operating device, wherein the configuration information includes an address information and the configuration element generates the address information due to an approach of a permanent magnet.

The configuration element can also be arranged in the operating device and at least recognize an approach of a permanent magnet.

In summary, the invention discloses an improved addressing of a lamp operating device, which is characterized in that the address assignment can be made without direct contact or even opening a lamp.

Claims (19)

Claims 1. A method for controlling at least one light source, wherein - the light source is operated by an operating device, - the operating device is connected via a first interface with a control unit and optionally with other operating devices, wherein the operating device according to the control signals received via the first interface the lighting device operates, - the operating device has at least one further interface for connecting a sensor, in particular a brightness sensor, - a configuration element which is connected to the further interface of an operating device and which transmits configuration information to the operating device, - wherein the configuration information is an address information includes and the configuration element generates the address information due to an approach of a permanent magnet. 2. lighting system for controlling at least one light source, comprising - at least one operating device for operating the light source, wherein the operating device has a first interface and this interface is connected to a control device and optionally to other operating devices, - wherein the operating device according to the on the control device operates at least one further interface for connecting a sensor, in particular a brightness sensor, a configuration element which is connected to the further interface of an operating device and which transmits configuration information to the operating device, wherein the configuration information includes address information, and the configuration item generates the address information based on an approximation of a permanent magnet. 3. Lighting system according to claim 2, characterized in that the configuration element has a memory, which is preferably non-volatile and can be described several times. 4. Lighting system according to claim 2 or 3, characterized in that via the further interface, a unidirectional or bidirectional communication between the operating device and the configuration element is made possible. 5. Lighting system according to one of claims 2 to 4, characterized in that the operating device can be placed over the first interface in an addressing mode. 6. Lighting system according to claim 5, characterized in that the configuration element comprises means for detecting the approach of a permanent magnet and that the operating device receives the address information from the configuration element when the operating device has been placed in the addressing mode and the configuration element detects an approach of a permanent magnet. 7. Lighting system according to claim 5, characterized in that - the configuration element comprises means for evaluating the approach of a permanent magnet and that the operating device receives the address information from the configuration element, - the configuration element in evaluation of the approach of a permanent magnet, the address information either directly to the operating device transmits or generates itself when the operating device has been set to the addressing mode. 8. Lighting system according to one of claims 2 to 4, characterized in that the configuration element has means for evaluating the approach of a permanent magnet and that the operating device receives from the configuration element the Adressinfor- mation, the configuration element can put the operating device in an addressing mode, and if the operating device has been placed in the addressing mode, in evaluation of the approach of a permanent magnet, the address information either continues to be transmitted directly to the operating device or generated itself. 9. Lighting system according to one of claims 2 to 8, characterized in that the configuration element can additionally receive control information via a radio signal, and depending on these control information changes the operation of the light source according to the newly acquired configuration information. 10. Lighting system according to claim 9, characterized in that the radio signals are transmitted by means of a standardized transmission such as WLAN, Bluetooth or Zigbee. 11. Lighting system according to one of claims 2 to 10, characterized in that it is the lamp is an organic or inorganic LED or is a gas discharge lamp (fluorescent lamp, high-pressure gas discharge lamp). 12. Lighting system according to one of claims 2 to 11, characterized in that when replacing an operating device certain operating data can be transmitted via the configuration element of the exchanged to the newly inserted operating device. 13. Lighting system according to one of claims 2 to 12, characterized in that via the further interface, a power supply of the configuration element by the operating device. 14. Lighting system according to one of claims 2 to 13, characterized in that the configuration element is connected in addition to a sensor to the further interface. 15. Lighting system according to one of claims 2 to 13, characterized in that the configuration element is connected instead of a sensor to the further interface. 16. Lighting system according to one of claims 2 to 15, characterized in that the configuration element is marked in color. 17. Lighting system for controlling at least one light source, comprising - at least one operating device for operating the light source, wherein the operating device has a first interface and this interface is connected to a control device and optionally to other operating devices, - wherein the operating device according to the over the control unit is connected to a configuration element which transmits configuration information to the operating device, wherein the configuration information includes address information and the configuration element generates the address information due to an approach of a permanent magnet. 18. Lighting system according to claim 17, characterized in that the operating device can be placed over the first interface in an addressing mode. 19. Lighting system according to claim 18, characterized in that the configuration element has means for detecting the approach of a permanent magnet and that the operating device receives the address information from the configuration element when the operating device has been placed in the addressing mode and the configuration element detects an approach of a permanent magnet. For this 1 sheet drawings