WO2020187616A1

WO2020187616A1 - Address allocation and configuration of components of a lighting system using light signals

Info

Publication number: WO2020187616A1
Application number: PCT/EP2020/056138
Authority: WO
Inventors: Frank Lochmann; Lukas MOOSBRUGGER; Florian Moosmann; Fabio Romano
Original assignee: Tridonic Gmbh & Co Kg
Priority date: 2019-03-18
Filing date: 2020-03-09
Publication date: 2020-09-24
Also published as: AT18170U1; DE102019106735A1

Abstract

The invention relates to a controller for a component (3) of a lighting system. The controller (1) has a data storage device (6), a light receiving unit (7) for receiving a light signal which is modulated in order to transmit data, a demodulation module (9) which is connected to the light receiving unit (7) and which is designed to ascertain the data transmitted by the light signal at least when the controller (1) is deactivated and store the ascertained data in the data storage device (6), and a control device (5) which is designed to read the data stored in the data storage device (6) at least after the controller (1) has been activated and use same in order to control the component (3) to be controlled by the controller (1).

Description

description

Address assignment and configuration of components of a lighting system by means of light signals The present invention relates to a control device for a component of a

Lighting system, an operating device for lamps, a transmitting device for address allocation and / or configuration of the control device and / or the component, a one

Control device and a transmission device having lighting system and a method for transmitting data to be used for the control or configuration of the component by a control device from a transmission device to the control device controlling the component.

In addition to lights, lighting systems can have other components such as sensors or actuators, switches and dimmers. With the help of operating devices for the supply of the lamps of the lights, such as gas discharge lamps, halogen lamps and in particular light emitting diodes (LED), the function of the lamps can be monitored and can

Lights can be started and / or dimmed and switched off. By means of sensors, which e.g. Detecting movements of objects and / or the ambient brightness, the lighting means can be switched on / off automatically in the presence / absence of a person, or the dimming of the lighting means can be automatically adapted to the ambient brightness.

In particular, operating devices of lights with light emitting diodes (LED) often contain

Control devices which can receive control data for the setting of operating parameters, such as the maximum output current to the light-emitting diodes or the color temperature, from the outside. In lighting systems in which the components are used to

Data exchange are networked, the components are each connected to a control device which, among other things, controls the data exchange for operation in a network and identifies the component in the network through its unique assignment.

US 2012/0306621 A1 discloses a control device for a component which can be networked in a lighting system and which can wirelessly send and receive data to a writing and reading device by means of a transponder. The transponder is an RFID (radio-frequency identification) transponder which is connected to a control device and has an unmistakable identifier (UID, user identification) that can be read out by a central control unit. This identifier is used to identify the components in the to identify first commissioning or when switching on the lighting system by the central control unit in order to be able to automatically assign network addresses to them.

With the lighting system, however, there is the problem that the address is only assigned after the lighting system has been switched on and the installer / user of the

Lighting system does not have any influence on the assigned addresses when the RFID addresses are used automatically if the identifier (UID) of the respective component or transponder is unknown to it. In addition, the components cannot be parameterized and configured by the installer before they are switched on or commissioned for the first time. Since data transmission is only possible within short distances, the installer has to position the writing and reading device very close to the transponder, which is time-consuming and therefore expensive for devices installed in inaccessible places or high ceilings. The invention is based on the object of specifying a device and a method which reduce the problems described. The object is in particular to provide a control device, an operating device for lighting means, a transmission device, a lighting system and a method with which the control devices of components of a

Lighting system can be addressed and / or configured in a simple manner before commissioning.

This object is achieved according to the features of the independent claims. The

The invention is further developed by the features of the dependent claims. According to the present invention, a control device for a component of a lighting system has a data storage device, a light receiving unit

Demodulation module and a control device. The light receiving unit serves to receive a light signal that is modulated for data transmission and outputs a signal reproducing the transmitted data to the demodulation module via a cable or a radio link. The demodulation module is designed to determine the transmitted data at least when the control device is switched off or in a currentless state and to store the determined data in the data storage device.

The data transmission by means of light signals enables configuration and addressing even from a great distance, with the light being transmitted by the light receiving unit

received light signal simultaneously for the energy supply of at least the Demodulation module and the data storage device can be used for storing and possibly checking the received data if the light receiving unit is a photovoltaic unit. For this purpose, the demodulation module for the determination and

Storage of the data fed by the voltage output by the light receiving unit or the photovoltaic unit. This makes it possible to configure while the device is switched off without any further measures. This means that the respective component can be transferred to the local

The configuration is done.

Alternatively or additionally, the demodulation module and the data storage device can be supplied by an internal energy store when the control device is switched off. The energy store can be formed from a battery, an accumulator and / or capacitor. The accumulator and / or the capacitor can be fed by the voltage output by the photovoltaic unit, i.e. can be charged by the ambient light and / or the modulated light signal. The light receiving unit can be formed from one or more photodiodes or solar cells.

The light receiving unit can be detachably connected to the control device so that the light receiving unit can be removed from the control device again after the configuration and addressing. For places that are difficult to access, however, it is preferred to integrate the light receiving unit into the respective component so that after the

Configuration or commissioning, the light receiving unit remains in the component. Editing the component again to remove the

The light receiving unit can then be omitted. However, the costs are multiplied, since reuse of the light receiving unit, which was created after the configuration or

Picking is no longer needed becomes impossible.

The data stored in the data storage device can be read out when the control device is first started up or after each time it is switched on. Reading out the data after each switch-on has the advantage that changes affecting the configuration are saved immediately. The data can contain at least information on the configuration of the control device itself and / or information on the configuration of the component to be controlled by the control device, the control device being designed to configure the control device and / or the component to be controlled by the control device according to the information. Additionally or alternatively, the data can contain addressing information which indicates a network address with which the control device can be identified with respect to control devices of other components of the lighting system. Since this addressing information can already be stored in the respective component in the currentless state, simplified commissioning is possible during the construction phase of a building.

The control device can have an interface by means of which the control device can be connected to the control devices of other components of the lighting system, so that data received by the light receiving unit and addressed to several control devices or the other control devices or components can be forwarded via the interface. For this purpose, if the received data have a network address of another control device, the demodulation module sends the data to this network address via the interface.

In addition, the interface can be designed to connect the other control device for storing the data in a data storage device with one of the

To supply light receiving unit generated energy. This can be particularly advantageous if a direct supply of the other control device according to the invention is not possible, for example due to a difficult spatial situation, but the other control device is within the range of an accessible control device. The control device according to the invention is thus used as a kind of relay station.

The control device can have a transmitter which is fed directly or indirectly by the voltage emitted by the light receiving unit and is designed to send a signal indicating the successful storage of the data to a transmitting device transmitting the light signal or the user of the transmitting device. The transmitter can be a control LED that can be controlled by the demodulation module and that indicates to the user the successful storage or possibly transmission errors with a specific luminous color and / or flashing pattern.

Alternatively, the control device can be designed to be currently used

Control data, information about currently set configurations of the control device and / or the component to be controlled by the control device and / or functional errors of the control device and / or the component and to determine in the To store data storage device, the transmitter controlled by the demodulation module transmitting the stored control data, information and / or functional errors to the transmitting device sending the light signal upon request. The transmitter can be an infrared transmitter or a Bluetooth low energy transmitter.

According to the present invention, an operating device for lighting means has one of the control devices described above. The lighting means can be an LED module consisting of several light-emitting diodes. According to the present invention, a transmitting device for transmitting data to one of the control devices described above has a device for determining the data to be transmitted to the control device, a light source for outputting the modulated light signal and a control unit. The control unit is designed to control the light source in such a way that the light emitted by the light source is modulated in accordance with a predetermined modulation method to transmit the specific data.

The light source can be constructed similarly to a laser pointer and can have at least one laser diode provided with a collimator lens in order to enable data transmission from great distances. Alternatively, for small distances, an LED provided for video or photo recordings on a smartphone or tablet can be used as a light source, with the device for determining the data to be sent and the control unit being integrated into the smartphone or tablet.

According to the present invention, a lighting system has at least one of the control devices described and one of the transmission devices described.

According to the present invention, a method for transmitting data to be used for a control or the configuration of a component of a lighting system by a control device from a transmitting device to the control device controlling the component has the following steps:

- Control of a light source of the transmitting device, so that the light emitted by the light source is modulated for the transmission of the data according to a predetermined modulation method,

- Receiving the modulated light signal with a light receiving unit of

Control device when the control device is switched off, - Determining the transmitted data from the signal output by the light receiving unit,

- Storage of the determined data in a data storage device,

Reading out the stored data from the data storage device after switching on the control device, and

- Controlling the component by the control device on the basis of the data read out and / or setting an address for the control device, which is indicated in the data and with which the control device can be identified with respect to control devices of other components of the lighting system.

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

1 shows a first embodiment of a lighting system with a control device and a transmitting device of the first embodiment according to the present invention,

FIG. 2 shows a second exemplary embodiment of a lighting system according to the present invention; FIG. 3 shows a third exemplary embodiment of a lighting system according to the present invention, and FIG

4 shows a simplified flow chart to illustrate the method according to the present invention.

Components with the same functions are identified by the same reference symbols in the figures. In order to avoid unnecessary repetitions, a repetitive description is dispensed with where this appears unnecessary. 1 shows a simplified schematic illustration of a lighting system with a control device 1 and a mobile transmitter 2, in particular for assigning network addresses and for configuration according to the present invention. The

Control device 1 is in particular an operating device for operating a light source 3, in which the parameters for operating the connected

Light source can be set. The lighting means 3 can comprise a light emitting diode (LED) or several LEDs. The LEDs can be inorganic or organic LEDs. The multiple LEDs can be connected in series or in parallel. The plurality of LEDs can also be connected in more complex arrangements, for example in a plurality of LEDs connected in parallel to one another

Series connections.

The control device 1, i.e. the operating device in the example shown, has a constant current converter 4 formed from a rectifier and a DC voltage converter, e.g. an LED converter which generates a current necessary for the operation of the LEDs from a mains voltage (not shown) when it is connected to the mains. Of the

Constant current converter 4 is controlled by a control device 5 in accordance with a predetermined configuration and a dimming signal which the control device 5 receives via a data bus (not shown). Information on the configuration, such as the maximum current to be supplied to the lamp 3 or the color temperature and a network address of the

Control devices 1 are stored in a non-volatile data storage device 6 and are read out by the control device 5 during commissioning. The control device 5 can be an integrated semiconductor circuit or comprise an integrated semiconductor circuit. The control device 6 can be designed as a processor, a microprocessor, a controller, a microcontroller or an application-specific special circuit (ASIC) or a combination of the named units.

The control device 1 has a photovoltaic unit 7

Light receiving unit, an energy store 8 fed by the photovoltaic unit 7, and a demodulation module 9 coupled to the photovoltaic unit 7 and supplied with energy by the energy store 8. The photovoltaic unit 7 contains at least one photocell and emits a voltage when light falls, which voltage is fed to the energy store 8. In a very simple embodiment, the energy store 8 can consist of a diode and a capacitor to be charged via the diode.

The transmitting device 2 is used to contact the control device 1

configure / parameterize and has a light source 10 for emitting light to the photovoltaic unit 7, a display unit 11 for displaying the to be transmitted or

selectable data, an input unit 12 for inputting and selecting the data and one connected to the light source 10, the display unit 11 and the input unit 12 Control unit 13 on. The input unit 12 can be integrated into the display unit 11 (touch-sensitive screen). For mobile use, the transmitter 2 is equipped with an internal battery (not shown). This also supplies the energy for the light source 10 or feeds the energy store 8 via the light emitted to the photovoltaic unit 7. The light source 10 emits a light bundled by means of a reflector and / or a lens. The light intensity emitted and the concentration depend on the distance between the light source 10 and the photovoltaic unit 7 and the nature of the photovoltaic unit 7. In applications with a large distance, the light source can be constructed like a laser pointer and have a laser diode provided with a collimator lens. It is also possible to provide different light sources for different distances, one of which can be selected by the user by means of the input unit 12.

For the transmission of the selected data to the control device 1, the light emitted by the light source 10 to the photovoltaic unit 7 is modulated. In addition, the control unit 13 controls the light source 10 in accordance with a predefined modulation method and a data transmission protocol. The modulation method can be amplitude, phase, pulse width or frequency modulation. Since the energy for the demodulation and storage of the data in the control device 1 is supplied by the light source 10, a modulation method with a high effective light output should be selected. In the case of pulse width modulation, the meanwhile missing

Energy transfer, an energy storage device is absolutely necessary on the component side, which can be omitted with the other modulation methods.

The modulated light emitted by the light source 10 is directed onto the photovoltaic unit 7 by the user by aligning the transmitter 2. The photovoltaic unit 7 emits a voltage corresponding to the modulated light, which charges the energy store 8 or the capacitor via which the demodulation module 9 is fed. The demodulation module 9 thus supplied with energy detects the profile of the voltage output by the photovoltaic unit 7 and demodulates the transmitted signal. If the data contained in the transmitted signal have a correction code, the demodulation module 9 checks and corrects the received data by means of the code and stores the data in the data storage device 6 after a successful check or correction.

In order to prevent data intended for another control device from being erroneously received and stored, the transmitted data can be provided with an address or identification information for the control device 1. The Demodulation module 9 compares the address or identification information contained in the received data with the address or identification information stored in the data storage device 6 and only stores the data if the addresses or identification information match. As an alternative or in addition, the data can be encrypted in the transmitter 2 and decrypted by the demodulation module 9 using a key stored in the data storage device 6.

The data transmission and storage can take place in the switched-off state, in which the control device 1 is disconnected from the mains voltage or not yet connected to it, or in the switched-on state. If the control device 1 is switched on or supplied with energy, the control device 1 reads out the data stored in the data storage device 6 and parameterizes / configures the operating device or the

Control device 1. The transmitter 2 can also be used to assign the control device 1 an address in a lighting system consisting of a large number of components. So that the components of a lighting system can transmit data with one another and / or with a central controller during initialization and / or operation, each component requires a network address. According to the present invention, this address can be set in a simple manner before the respective

Allocate components and transmit them to the control device 1 by means of the transmitter 2.

The control device 1 and the lighting means 3 can be integrated in one device, for example an emergency light having a storage battery. Emergency lights are in

Continuous switching (with mains operation ON) or in standby mode (with mains operation OFF, only ON in the event of a power failure). The emergency lights are often on permanently

preset. In order to switch from permanent switching to standby switching, a wire bridge must often be removed from the emergency luminaire, especially in the case of non-network-compatible luminaires or those that are not operated in a network, which is time-consuming and error-prone due to the partial disassembly required for this. According to the present invention, the selection / configuration of permanent switching or standby switching by means of the input unit 12 of the transmitting device 2 can be carried out by the user without opening the device or mechanical processing, with corresponding data from the control unit 13 generated and sent wirelessly to the control device 1 by means of the modulated light. Such a configuration can be carried out quickly with the transmitter 2 even with a large number of emergency lights. Since the data transmission is also possible when the emergency light is in a currentless or uncharged state, the configuration can be carried out at a location different from the intended installation location of the emergency light, for example in a warehouse, using a stationary transmitter 2.

The transmitting device 2 can repeatedly send the data to the control device 1 during a connection up to the expiry of a certain period of time in order to ensure that the data have been received and that sufficient energy has been transmitted for its processing.

Additionally or alternatively, the successful data transmission and storage can be indicated to the user by an acoustic or optical signal from the control device 1, so that he can end or repeat the data transmission. It is also possible to measure the voltage output by the photovoltaic unit 7 by the demodulation module 9, to compare it with a threshold value and to indicate to the user by means of an optical signal that the photovoltaic unit 7 is currently outputting a sufficiently high voltage for data processing when the Voltage exceeds the threshold. Information about the successful data transmission and storage can alternatively be sent from the control device 1 to the transmitting device 2, so that the transmitting device 2 can automatically stop or repeat the data transmission. The information can be transmitted by means of a radio link or an infrared light-emitting diode provided on the control device 1 and an infrared signal receiver provided on the transmitter 2. Fig. 2 shows an example of such a lighting system, in which the information about the successful data transmission and storage and possibly other information to the

Transmitter 2 can be transmitted.

The control device 1 shown in Fig. 2 additionally has a transmitter 14 and the

Transmitter 2 has a corresponding receiver 15. The transmitter 14 is of the

Energy store 8 supplied with voltage and controlled by the demodulation module 9 or fed with the data to be sent. The receiver 15 receives the data sent by the transmitter 14 and transmits them to the control unit 13, which evaluates the data and stops the data transmission by means of the modulated light or, if necessary, repeats it with increased light intensity. The transmitter 14 and the receiver 15 can use Bluetooth Low

Be an energy transmitter. Alternatively, data can also be sent from from the transmitter 2 to the control device 1, the energy supply being provided by the photovoltaic unit 7 or the energy store 8.

The connection between the transmitter 14 and the receiver 15 can also be used to transmit data stored in the data storage device 6, such as the network address or identification information of the control device 1 and / or the operating parameters, to the transmitter 2. The transmitting device 2 can send a command for the transmission of the data by means of the modulated light signal to the control device 1, the demodulation module 9 reading out the requested data from the data storage device 6 and outputting it to the transmitter 14 for transmission. The transmitting device 2 can display the transmitted operating parameters for checking or changing the parameters and, if necessary, can send changed parameters to the control device 1. In order to prevent old parameters or parameters of another control device 1 from being used by the demodulation module 9 in the

Data storage device 6 are stored, the demodulation module 9 can generate transaction information, for example a random number, send this linked to the parameters to the transmitting device 2 and the received parameters only after a successful check of the parameters linked to the received parameters

Save transaction information. 3 shows a section of a third exemplary embodiment of a lighting system according to the present invention, in which data received from a control device 1b can be forwarded to another control device 1a, 1c, 1d. The lighting system shown in Fig. 3 includes a transmitter 2 and a plurality of

Control devices la..ld which are connected to one another via a bus system 16. Each of the control devices la..ld is assigned its own network address. Two of the

Control devices lb, ld each have a photovoltaic unit 7b, 7d, one

Data storage device, a demodulation module and a control device as described above. In addition, the demodulation modules of the control devices 1b, 1d are connected to the bus system 16 via an interface (not shown).

The transmitting device 2 transmits data as described above to one of the control devices 1b or 1d, the data being sent to one or more of the network addresses using the network addresses

Control devices la..ld are addressed. A network address contained in the data is detected by the demodulation module in order to determine whether the data are addressed to this or to another control device la .. ld. Are the data to someone else

Addressed control device la..ld, the demodulation module sends the data via the Interface to the specified network address or to the other control device la..ld which stores the data. The energy supply for the transmission and storage in the other control device la .. ld can take place with the energy generated by the photovoltaic unit or the energy stored in the energy store 8.

The photovoltaic unit 7, 7b, 7d is fixed to the in the examples described

Control device 1, la..ld connected. However, it is also possible to connect the photovoltaic unit 7, 7b, 7d to the control device 1, la .. ld via a plug connection, so that the photovoltaic unit 7, 7b, 7d can be removed from the control device 1, la .. ld after the data transmission is. The photovoltaic unit 7, 7b, connected to the control device 1, la..ld

7d can be designed and positioned so that it only supplies the demodulation module 9 with energy during the data transmission or at least partially charges the energy store 8 with energy from the ambient light before the data transmission. The signals emitted by the photovoltaic unit 7, 7b, 7d can be sent via a radio link, for example, to a transponder of the control device 1, la..ld, which stores the data and has the demodulation module 9 and the data storage device 6 and from which the stored data from Control device 1 can be read out after switching on. Alternatively, instead of the photovoltaic unit 7, 7b, 7d, one or more photodiodes and / or solar cells can be used for the data transmission. The demodulation module 9 can be fed by the photodiodes, a battery or an accumulator that is charged from a source other than the transmitter 2. The control device 1, la .. ld can be integrated into the component 3 to be controlled by the control device 1, la..ld, such as, for example, in a lamp that has the

Control device 1, la..ld, the constant current converter 4 and the lighting means 3 contains. The components can be lights, operating devices for lighting means, integrated LED lamps or other control and / or configurable components such as actuators or sensors.

A greatly simplified flowchart is shown in FIG. 4, which shows the individual steps in carrying out the method described in detail above.

Claims

Expectations

1. Control device for a component (3) of a lighting system, wherein the

Control device (1) has:

a data storage device (6),

a light receiving unit (7) for receiving a light signal modulated for data transmission,

a demodulation module (9) connected to the light receiving unit (7), which is designed to determine the data transmitted by means of the light signal at least when the control device (1) is switched off and the data determined in the

To store data storage device (6), and

a control device (5) which is designed to operate in the

Data storage device (6) to read out stored data at least after switching on the control device (1) and to use them for controlling the component (3) to be controlled by the control device (1).

2. Control device according to claim 1, wherein

the demodulation module (9) for determining and storing the data is fed by the voltage output by the light receiving unit (7).

3. Control device according to claim 1, wherein

the control device (1) has an energy store (8) which is fed by the voltage output by the light receiving unit (7) and is designed to supply the demodulation module (9) with energy during the determination and storage of the data.

4. Control device according to one of the preceding claims, wherein

the light receiving unit (7) is detachably connected to the control device (1).

5. Control device according to one of the preceding claims, wherein

the data contain at least information on the configuration of the control device (1) itself and / or information on the configuration of the component (3) to be controlled by the control device (1); and

the control device (5) is designed to control the control device (1) and / or the component (3) to be controlled by the control device (1) in accordance with the

Configure information.

6. Control device according to one of the preceding claims, wherein

the data contain at least one addressing information item which indicates a network address with which the control device (1) is to be identified in the lighting system.

7. Control device according to claim 6, comprising

an interface by means of which the control device (1) can be connected to control devices (la..ld) of other components (3) of the lighting system, wherein

the data have a network address of another control device (la..ld) and the demodulation module (9) is designed to send the data via the interface to the network address.

8. Control device according to claim 7, wherein

the interface is designed to supply the other control device (l a..ld) for storing the data in a data storage device of the other control device with energy generated by the light receiving unit (7).

9. Control device according to one of the preceding claims, comprising

a transmitter (14) which is fed directly or indirectly by the voltage emitted by the light receiving unit (7) and is designed to transmit the successful

Saving the data indicating signal to a transmitting device (2) transmitting the light signal or to the user of the transmitting device (2).

10. Control device according to claim 9, wherein

the control device (5) is designed to receive currently used control data, information about currently set configurations of the control device (1) and / or the components (3) to be controlled by the control device (1) and / or functional errors of the control device (1) and / or to determine the component (3) and in the

Store data storage means (6); and

the transmitter (14) is designed to transmit the stored control data, information and / or functional errors to the transmitter (2) sending the light signal.

1 1. Control device according to claim 9 or 10, wherein

the transmitter (14) is an infrared transmitter or Bluetooth low energy transmitter.

12. Operating device for lamps with a control device according to one of the

previous claims.

13. Sending device for sending data to a control device according to one of the

preceding claims, wherein the transmitting device comprises:

a device (12) for determining the to be sent to the control device (1)

Data,

a light source (10) for outputting the modulated light signal, and

a control unit (13) which is designed to control the light source (10) in such a way that the light emitted by the light source (10) is modulated for the transmission of the specific data according to a predetermined modulation method, wherein

the light source (10) has at least one laser diode provided with a collimator lens.

14. Lighting system with at least one control device (1) according to one of the claims

1 to 11 and a transmitter (2) according to claim 13.

15. A method for transmitting data to be used by a control device (1) for a control or configuration of a component (3) of a lighting system from a transmitting device (2) to the control device (1) controlling the component (3), comprising the steps:

Controlling a light source (10) of the transmitting device (2), so that the light emitted by the light source (10) for the transmission of the data according to a predetermined

Modulation method is modulated,

Receiving the modulated light signal by means of a light receiving unit (7) of the

Control device (1) when the control device (1) is switched off,

Determining the transmitted data from the signal output by the light receiving unit (7),

Storing the determined data in a data storage device (6),

Reading out the stored data from the data storage device (6) after

Switching on the control device (1), and

Controlling the component by the control device (1) on the basis of the data read out and / or setting an address displayed in the data for the

Control device (1) with which the control device (1) can be identified with respect to control devices (la..ld) of other components (3) of the lighting system.