DE202006007896U1 - Lighting system e.g. for buildings, has synchronizing RF-interface connected to two control appliances - Google Patents

Abstract

A lighting system with several controlled lighting units (B1-Bn) in which each control appliance (S1-Sn) has an interface for bidirectional transmission of data. Each control appliance (S1-Sn) of each lighting unit (B1-Bn) has a synchronizing RF-interface (3) via which it is connected to a maximum of two control appliances of two adjacent lighting units (B1-Bn), and at least one of the control appliances of the linear network lighting units can be connected via its RF-interface (3) to an operation-, start-up, and maintenance tool (PDA).

Description

The Invention is based on a generic term of the main claim designed lighting system.

such Lighting systems are meant to be over their Lighting units inside or outside of buildings for a targeted illumination their environment or for the illumination of objects directly in their environment or Persons or for an ambient lighting, signaling, lighting games, etc. to provide. Do such lighting systems have a variety of lighting units It is important that these are simple and understandable Way can be installed and put into operation and that changes on an existing lighting system in a simple way feasible are. Furthermore is it important for that certain light stagings the lighting units long term be operated sufficiently synchronously so that it does not get too ugly or irritating light stagings comes.

An according to the preamble of the main claim lighting system is characterized by the DE 197 56 705 C2 known. This lighting system has a plurality of optionally controllable lighting units belonging to a network. Each illumination unit is provided with its own lighting control device with its own control unit, which has an interface for a bidirectional secure transmission of data, a flow control, a power level and a power supply. Such a design, however, makes it necessary for the lighting units of the lighting system to be put into operation during a new installation, initial startup or restarting operation by means of a specific, fixed addressing set to each lighting unit, which causes a correspondingly high outlay. Moreover, in such a lighting system, when radio components are to be integrated, it is difficult to ensure, over a longer period of time, that the timings of the control units are synchronized.

Of the The present invention is therefore based on the object, a lighting system with several lighting units combined in a linear network in which both the initial start-up and a Extension or replacement of lighting units on extra simple way possible and which ensures that these have a longer Period are operated in a particularly high degree synchronously can, so that it does not synonymous with fast changing lighting scenes too unsightly Apparitions is coming.

According to the invention this Task by those described in the characterizing part of the main claim Characteristics solved.

at Such a design of a lighting system is particular advantageous that in a particularly simple way long-term an exact synchronicity the temporal processes the control units brought becomes.

Further advantageous embodiments of the subject invention are in the dependent claims specified. Based on an embodiment Let the invention be closer in principle explained. Showing:

1 in principle a block diagram of a lighting unit of such a lighting system with the associated control unit;

2 in principle, such a lighting system with several belonging to a linear network, optionally controllable lighting units.

As can be seen from the figures, such a lighting system has a plurality of lighting units B1 to Bn belonging to a linear network and optionally controllable. Each lighting unit B1 to Bn is equipped with its own control device S1 to Sn, via which the lighting device belonging to each lighting unit B1 to Bn, designed as an LED 2 can be influenced. The designed as LED bulbs 2 are designed in such a way that they can emit light in different colors of light.

As can further be seen from the figures, each control device S1 to Sn has a radio interface 3 on. The radio interface 3 Each control device S1 to Sn is designed according to the Bluetooth standard and provided for a bidirectional data connection. Each control unit S1 to Sn and thus each lighting unit B1 to Bn is technically via its radio interface 3 maximum with two adjacent controllers S1 to Sn of the network in connection. In the present exemplary embodiment, the first illumination unit B1 communicates via its first control unit S1, on the one hand, with the second control unit S2 of the second illumination unit B2 and, on the other hand, in terms of data, with a control, start-up and maintenance tool designed as a "personal digital assistant" PDA. The last illumination unit Bn is in the present embodiment on their last control unit Sn data technology on the one hand with the penultimate control unit S4 of the penultimate th lighting unit B4 and the other data technology with a search unit 4 in connection. The second illumination unit B2 and the third illumination unit B3 are in the present embodiment via their second control unit S2 and their third control unit S3 data technology with the two directly adjacent control units S1 and S3 or S2 and S4 and thus with the two directly adjacent lighting units B1 and B3 or B2 and B4 in terms of data technology.

As further in particular from 1 shows, each controller S1 to Sn not only a radio interface 3 on, but is also with a flow control 5 , a performance level 6 and a power supply 7 equipped. The power supply 7 supplies both the radio interface 3 , the flow control 5 , as well as the power level 6 with the power necessary for operation. Starting with the from the radio interface 3 received data is first the flow control 5 which then affects the power level 6 according to the available data, the bulbs 2 controls. The bulbs 2 stand for the reporting of different measured values again in terms of data with the flow control 5 in connection.

Thus, in a simple way, even complex light staging over the radio interfaces 3 can run, each control unit S1 to Sn is able to autonomously control the lighting 2 his respective associated lighting unit B1 to Bn make. Thus the radio interfaces become 3 during operation of the lighting system only needed so that the lighting scenes over a long period of time particularly synchronously or exactly run. Advantageously, such a lighting system operates less susceptible to interference and disseminates less, other radio systems interfering radio signals.

For long-term exact synchronization of the time sequences influenced by the control units S1 to Sn, the first control device S1 of the linear network constructs an unsecured, unidirectionally operating radio channel several times within a certain period of time. An unsecured, unidirectional radio channel offers in this context the advantage of easily reproducible running times of the transmitted data. These run times are by means of a in the flow control 5 integrated transit time measuring device 8th determined and then used in a simple manner in the synchronization as compensation values. Each control unit S1 to Sn also has its own clock, so is in the phases between the synchronization signals a particularly synchronous working or driving the light source 2 guaranteed.

When the lighting system is first started up, all the lighting units B1 to Bn first switch on their sequence control 5 integrated search unit 4 one. This is necessary because until then none of the lighting units B1 to Bn knows their position in the linear network and thus the positions of the neighbors are not known. However, once one of the lighting units B1 to Bn via its search unit 4 has found a neighbor, this neighbor is informed that it is the second illumination unit B2 in the linear network of the illumination system. The lighting unit B1 to Bn, which has found its neighbor, then switches their search unit 4 and explains itself at the same time as the first illumination unit B1 of the linear network.

The Search for further neighbors or for further direct neighbors In principle, it continues in the same way until the last one Lighting unit Bn is fixed because no neighbor in the linear Network can be found. Thus, in general, simple results Way a linear network with several, in their positions certain lighting units B1 to Bn. Every lighting unit B1 to Bn now also know how many other lighting units B1 to Bn are present in the linear network and which position take these in the linear network.

Should in exceptional cases within a linear network at initial startup subnetworks are formed because, for example, two lighting units B1 to Bn respectively to the first illumination unit B1 of the linear Network, a communication process is set in motion, to merge the subnetworks into a single linear network. To the communication process is the positioning of the lighting units B1 to Bn then again clearly regulated.

With a normal switching on of the illumination system, as already described, the positioning of the illumination units B1 to Bn in the linear network is clearly regulated. Otherwise there are no special occurrences, the lighting system is put into operation in its known linear structure. Falls z. B. a lighting unit B1 to Bn or is a lighting unit B1 to Bn dismantled, etc., then the directly adjacent lighting unit B1 to Bn tried with the next but one neighbor on their search unit 4 To get in touch. If such a connection succeeded, the positioning of the lighting units B1 to Bn in the linear network is re-regulated until it is clear that the currently last lighting unit Bn is fixed. The then last lighting unit Bn is then informed, which lighting unit Bx failed or missing and charged with the search for this lighting unit Bx. Once the failed or missing lighting unit Bx through the search unit 4 the last illumination unit Bn was found, this is again clearly integrated into the linear network. Otherwise, this lighting unit Bn is declared as the last of the linear network.

For a quick and easy operation, commissioning, as well as for the simple and rapid change of functional sequences, the first control device S1 of the first illumination unit B1 stands, in particular 2 shows, in conjunction with a "Personal Digital Assistant" PDA. Using the "Personal Digital Assistant" PDA, all settings necessary for controlling or influencing the lighting system can be user-friendly via a radio link when using the radio interface 3 the lighting units B1 to Bn are made, which is also very advantageous.

Consequently is a lighting system created in which both the initial commissioning as well as an extension or replacement of lighting units B1 to Bn or a change of functionalities is possible in a particularly simple manner and which also it is ensured that the lighting units belonging to a linear network B1 to Bn over a longer one Period are operated in a particularly high degree synchronously can, so that it does not synonymous with fast changing lighting scenes too unsightly Apparitions is coming.

Claims (17)

Illumination system with a plurality of lighting units (B1 to Bn) belonging to a network and optionally controllable, each having a control device (S1 to Sn) and at least one lighting device (S1 to Sn) which is influenced by the control device ( 2 ), wherein each control device (S1 to Sn) has an interface for a bi-directionally secure transmission of data, a sequence control ( 5 ), a performance level ( 6 ) and a power supply ( 7 ), characterized in that each control device (S1 to Sn) of each illumination unit (B1 to Bn) also serves for synchronization radio interface ( 3 ) and, in terms of data technology, is in communication with a maximum of two control units (S1 to Sn) of two adjacent lighting units (B1 to Bn) of a linear network, and that at least one of the control units (S1 to Sn) of the lighting units (B1 to Bn) of the data from a linear network via its radio interface ( 3 ) can be connected to an operating, commissioning and maintenance tool (PDA), and that each control device (S1 to Sn) has a connection via its radio interface ( 3 ) operable search unit ( 4 ), and that each control device (S1 to Sn) for self-sufficient control of the lighting means ( 2 ) of the respective associated illumination unit (B1 to Bn) is executed. Lighting system according to claim 1, characterized in that the first control device (S1) of the first illumination unit (B1) of the linear network via its radio interface ( 3 ) is connected on the one hand to a single control device (S2 to Sn) of an adjacent illumination unit (B1 to Bn) and, on the other hand, via its radio interface ( 3 ) is connectable to the operating, commissioning and maintenance tool. Lighting device according to one of claims 1 or 2, characterized in that the last control device (Sn) of the currently last illumination unit (Bn) of the linear network via its radio interface ( 3 ) is connected on the one hand to a single control device (S1 to S4) of an adjacent illumination unit (B1 to B4), and on the other hand via this radio interface ( 3 ) the search unit ( 4 ) is operable. Lighting device according to one of claims 1 to 3, characterized in that for long-term, exact synchronization of the timing of the control devices (S1 to Sn) of the linear network via the radio interface ( 3 ) of a single specific control device (S1 to Sn) of the linear network is a number of times within a certain period of time briefly an unsecured radio channel can be built. Lighting system according to claim 4, characterized in that via the radio interface ( 3 ) of the specific control device (S1 to Sn) of the linear network buildable unsecured radio channel is executed unidirectionally working. Lighting system according to claim 4, characterized in that via the radio interface ( 3 ) of the specific control device (S1 to Sn) of the linear network constructible unsecured radio channel is executed bidirectionally working. Illumination system according to one of Claims 1 to 6, characterized in that at least one of the control devices (S1 to Sn) of the illumination units (B1 to Bn) of the linear network has a transit time measuring device (FIG. 8th ) having. Illumination system according to one of claims 1 to 7, characterized in that for long-term, exact synchronization of the temporal sequences, all the control devices (S1 to Sn) have their own clock and in that, when establishing a radio connection intended for synchronization, transmission of the current clock statuses via the radio interfaces ( 3 ) of the control devices (S1 to Sn) takes place. Lighting system according to one of claims 1 to 8, characterized in that at least one lighting unit (B1 to Bn) one over the associated control unit (S1 to Sn) influenceable motor positioning has. Lighting system according to one of claims 1 to 9, characterized in that at least one lighting unit (B1 to Bn) with a temperature value to the associated control unit (S1 to Sn) Temperature sensor is provided. Lighting system according to one of claims 1 to 10, characterized in that at least one lighting unit (B1 to Bn) with a light color value to the associated control unit (S1 to Sn) Light color sensor is provided. Lighting system according to one of claims 1 to 11, characterized in that at least one lighting unit (B1 to Bn) with a failure value to the associated control unit (S1 to Sn) Failure sensor is provided. Illumination system according to one of claims 1 to 12, characterized in that at least one radio interface ( 3 ) of the control devices (S1 to Sn) is executed according to the Bluetooth standard. Illumination system according to one of Claims 1 to 13, characterized in that at least one radio interface ( 3 ) of the controllers (S1 to Sn) is designed according to the Zigbee standard. Lighting system according to one of claims 1 to 14, characterized in that the operating, commissioning and Maintenance tool as "staff Digital Assistant "(PDA) accomplished is. Lighting system according to one of claims 1 to 15, characterized in that at least one lighting unit (B1 to Bn) at least one designed as a light emitting diode (LED) bulbs ( 2 ) having. Lighting system according to one of claims 1 to 16, characterized in that at least one lighting unit (B1 to Bn) comprises bulbs, which light in different colors of light radiate.