WO2016174080A1 - Method for identifying electrical lighting devices - Google Patents

Abstract

The invention relates to a method for identifying electrical lighting devices (1a-h) of a lighting structure (2), wherein the lighting devices (1a-h), which each have two electrical connection points (3a, b), are connected to the lighting structure (2) in a mechanically detachable manner and electrically at the connecting points (3a, b) according to a preferably predetermined topology, wherein the lighting devices (1a-h) each have a communication device (4) for transmitting an identifier (5) associated with the respective lighting device (1a-h), for receiving a switching instruction and for transmitting a voltage signal according to an input voltage applied at a first connecting point (3a), wherein each of the light devices (1a-h) produces an output voltage at a second connecting point (3b) on the basis of the received switching instruction, which output voltage is applied as an input voltage to said light devices (1a-h), with which there is an electrical connection at the second connecting point (3b), wherein a control device (6) receives the identifiers of the light devices (1a-h), wherein the control device (6) transmits switching instructions to at least some light devices (1a-h) in a plurality of steps, wherein after each step the control device (6) receives a voltage signal from at least one of the light devices (1a-h) and wherein the control device (6) on the basis of the received voltage signals assigns a position in the topology to the identifiers (5) of the light devices (1a-h).

Description

 Method for identifying electrical lighting devices

The present invention relates to a method for the identification of electrical lighting devices of a lighting construction with the features of claim 1.

From the prior art, it is known to compose a lighting assembly of a plurality of individual lighting devices. The lighting devices regularly have the possibility of being connected to one another in a variable configuration. In this case it is possible to use lighting devices which correspond to only a small number of variants or even all are essentially identical, but which are then assembled, aligned and connected flexibly in complex configurations. By means of such a modular system, on the one hand, the costs for individual preparations of lighting devices can be saved, but the flexibility in designing the overall lighting structure-both in terms of its shape and its dimensions-is maintained or is thereby obtained. In principle, this approach can be scaled to any size and allows both less extensive lighting fixtures with up to ten individual lighting fixtures as well as very complex lighting fixtures with thousands of lighting fixtures. The configuration of the luminous structure can on the one hand be regular on the one hand - for example, consist only of a single, repeating pattern - or be highly individual, so that almost no partial area of the luminous structure corresponds to another partial area. In such a lighting structure, it is also regularly desired that the individual lighting devices can be individually controlled with regard to their lighting behavior - on / off switching, dimming, setting of the color, in particular the color temperature, etc. Such control is carried out as desired and regularly by a control device, for. As a computer, which is with each individual Leuchtvorrich- device in telecommunications and possibly even wireless connection. The lighting devices are each distinguishable by an identifier or a network address in their control. Equally regularly, the lighting structure in its configuration - since it is either already known by the installation plan or comparatively easy to determine - is shown exactly in the control device. The problem in this situation is now the assignment of the positions of the configuration to the identifiers of the lighting devices. Thus, while the control device is regularly aware of all assigned identifiers of the illumination devices and also of all the positions present in the configurations, the assignment to the positions is regularly unknown a priori to the control device. Reading the identifier of the lighting devices during assembly of the lighting structure is either very difficult or impossible. Especially with the use of a larger number of identical lighting devices, it is advisable for rapid assembly that the mounting persons can simply pick a suitable piece of lighting equipment at random and mount it in place instead of using a needle in a haystack to have to pick out special lighting device with exactly the right identifier for each position with difficulty.

The invention is therefore based on the problem of simplifying the identification and assignment of light-emitting devices at their respective position within the topology of the light-emitting structure during assembly of such a light-emitting structure from individual light-emitting devices.

It has been recognized as essential for the invention that the individual lighting devices can already be arranged in a tree-like structure for the purpose of power supply. The term "tree-like structure" here and below does not mean a tree structure in the strict sense of graph theory, but rather an undirected connected graph in which at least one node has only one edge, which nodes are then designated as "root" can. In contrast to the unoriented tree of graph theory, the tree-like structure referred to here can have circles formed in particular by edges. The above idea is motivated by the fact that for such a voltage supply no separate supply line is laid to each individual lighting device, but the lighting devices themselves provide corresponding electrical connections with each other, so that only a few or only a single point - just If the individual light-emitting devices now have the option of transmitting an output voltage as a signal to light-emitting devices in the sense of the topology which corresponds to that of the "light source" Comprises feeding point outgoing tree-like structure as a pure compound structure, are directly adjacent, then, an identification method may ^* and gradually a complete assignment to perform further hangeln of a "root" of the tree-like structure successively ^"4. Such systematic Vorgehensvveise can thereby completely automated In this way, a time-effective assembly without regard to the individual identifiers of the lighting devices and a subsequent, full or largely automatic assignment and identification is achieved.

The preferred embodiment of claim 2 relates to the case that is selectively switched by a switching instruction which is applied to the lighting device input voltage. This allows a particularly simple implementation of the switching behavior.

It is interesting in the preferred embodiments of the subclaims 5 and 6 that by providing an alignment sensor on the light emitting devices, possibly established by a symmetrical connection structure uncertainties can be resolved. Especially if the lighting structure has many light-emitting devices and a larger number of lighting devices are regularly connected to each "node" of the tree-like structure, it may be that a pure determination of the connections underneath a unique assignment is not possible In this case, sensors which additionally can also determine the respective orientation of the lighting devices-which is regularly known in advance according to the installation plan-can produce unambiguousness through this additional information As a further variant of additional information for resolving uncertainties, geometric information is also provided, for example information about different lengths of the lighting devices.

The process of constructing the luminous structure is thereby further simplified if, as provided by dependent claim 15, the individual luminous devices are also invariant in their functionality, even with respect to a reversal of direction are. Then, during installation, no special attention needs to be paid to a special orientation of the lighting devices.

In the following the invention will be explained in more detail with reference to a drawing showing only an exemplary embodiment. In the drawing shows

1 shows a schematic representation of a lighting construction with lighting devices for the execution of the proposed method and

2 shows a schematic illustration of the internal structure of a lighting device from the lighting construction of FIG. 1.

The illustrated in Fig. 1 electrical lighting devices la-h form, for example, a lighting assembly 2 which is shown in Fig. 1 only in its connection structure. The interior - which is functionally identical here for each lighting device la-h - is likewise shown schematically in FIG. 2 by way of example for the lighting device 1a.

The proposed method is used to identify electrical lighting devices l ah a luminous structure 2. wherein the light emitting devices l ah, which each have two electrical connection points 3 a, b, releasably mechanically and at the connection points 3 a, b electrically according to a topology to the lighting structure are connected. The light-emitting devices 1a-h connected in this way both mechanically and electrically thus form the aforementioned luminous structure 2, the configuration in which the luminous devices la-h are connected to the luminous structure being referred to here as topology. The topology in the present sense thus includes the pure connection structure. However, it can also include further placement information (coordinates, alignments, etc.) of the lighting devices la-h in the real physical space. The topology can also be described as a 2D structure or 3D structure. Preferably, this topology is predetermined. This means that the topology z. B. has already been set in a construction plan before the mechanical and electrical connection of the lighting devices la-h was made to the light assembly 2. Then the proposed identification of the electrical lighting devices gen la-h the assignment of the individual lighting devices la-h to the building plan, in contrast to the creation of such a construction plan of a created lighting structure. 2

The connection structure of such a topology is shown by way of example in FIG. The electrical connection is thus produced at the connection points 3a, b of the lighting devices la-h, whereas the mechanical connection can in principle also be produced at another point of the lighting devices 1a-h. In the example of FIG. 1, for the sake of clarity, only the connection points 3a, b are entered for the lighting device 1a, wherein the other lighting devices 1b-h likewise have two connection points 3a, b in each case.

According to the proposal, the lighting devices la-h each have a communication device 4, which transmits an identifier 5 assigned to the respective lighting device 1, receives a switching instruction and transmits a voltage signal according to an input voltage applied to a first connection point 3a is set up. In this case, the first connection point 3a can be any one of the two connection points 3a, b, wherein the assignment is not fixed, but here only depends on which connection point 3a, b an input voltage is present.

The described communication device can thus both the respective identifier 5 shown in FIG. 1 - which is each represented by a different letter - the light emitting devices la-h transmit and receive a switching instruction in which switching instruction can be a signal in principle arbitrary , Likewise, the communication device 4 can transmit a voltage signal which is based on the input voltage applied to a first connection point 3a of the connection points 3a, b. In principle, this voltage signal can also be arbitrary and in particular be a binary signal which simply indicates whether or not there is a voltage that is different from the ground potential at the first connection point 3a, b. However, the voltage signal can also indicate the voltage level present at the first connection point 3a or the time profile thereof. According to the proposal, the lighting devices la-h respectively generate an output voltage at a second connection point 3b based on the received switching instruction. This second connection point 3b is any of the connection points 3a, b which is different from the above first connection point 3a. This output voltage is then proposed as an input voltage to those lighting devices la-h, with which there is an electrical connection at the second connection point 3b. Related to the example of FIG. 1, therefore, the output voltage which is generated at the second connection point 3b of the lighting device la, at the respective first connection point 3a of the light emitting devices lb and I d. The output voltage thus generated may also be a ground potential or a potential-free voltage.

In the proposed method, it is now provided that a control device 6, which by way of example is a computer, receives the identifiers 5 of the lighting devices la-h. In this way, the control device 6 has the information as to which lighting devices 1 a-h with their respective identifiers 5 are at all part of the luminous structure 2. The identifiers 5 can also be an address, identification number or character string of the communication protocol according to which the control device 6 communicates with the lighting devices la-h or with the respective communication device 4 of the lighting devices la-h ,

According to the proposal, it is now further provided that the control device 6 transmits switching instructions to at least some lighting devices 1 in several cases, the control device 6 receiving a voltage signal from at least one of the lighting devices 1 ah after each step, and the control device 6 based on the received voltage signals the identifiers 5 of the light emitting devices la-h assigns a position in the topology. Here, the identifier 5 of the lighting device la-h, which transmits the voltage signal, is also regularly received along with the voltage signal. In this case, the at least one lighting device 1 a, from which the voltage signals are received, is regularly different from the at least some lighting devices 1 a-h to which the switching instructions were previously transmitted in the relevant step. It can also be around each only a lighting device la-h act, from which a voltage signal is received or to which the switching instruction is transmitted.

By way of example, in such a step the control device 6 of the lighting device 1a can transmit a switching instruction, so that the lighting device 1a has a predetermined output voltage, e.g. B. a high voltage level, generated at the second connection point 3b. This second connection point 3 b of the lighting device 1 a forms in each case a first connection point 3 a of the lighting devices 1 b and 1 d. Then the control device 6 would receive from the lighting devices 1 b and 1 d a voltage signal which corresponds to this high voltage level. In turn, a switching instruction can be transmitted to the remaining lighting devices 1 b-h, to which, in particular, the respective second connection point 3b is to be switched potential-free. In such a case, only the lighting devices 1b and 1d would receive the above high voltage level as the input voltage at the first connection point 3a. The control device 6 can deduce from the above voltage signals of the lighting device 1 b and 1 d and note that the lighting devices 1 b and 1 d are each connected to the latter at the second connection point 3 b of the lighting device 1 a. It may then either be that the remaining lighting devices 1c, e, f, g, h transmit no voltage signal at all to the control device 6 or transmit a voltage signal indicating that they do not receive a high voltage level at a respective connection point 3a, b.

Preferably, the lighting devices la-h are each switchable between a switched-on switching state and a switched-off switching state, wherein in the switched-on switching state, the input voltage applied to the first connection point 3a is switched through as the output voltage to the second connection point 3b. Here, it is further preferred that in the switched-off switching state, the two connection points 3a, b are electrically separated. An example of such a circuit for this variant is shown in FIG. 2.

In principle, both the applied input voltage and the generated output voltage for the respective lighting device la-h can have any function, for example as voltage on a signal or control device. management for a further purpose. It may also be that the input voltage and / or the output voltage otherwise has no function at all. According to this circuit shown in FIG. 2, it is particularly preferred that the communication device 4 is supplied by the input voltage. Likewise, the luminous element 7a, which emits light, is supplied with an associated luminous regulator 7b from the input voltage. In this way, in response to the Schaltan instruction only those lighting devices la-h are ever supplied with a voltage for operation, at their junction 3a, b is applied a corresponding input voltage. The other lighting devices la-h are therefore switched off, since no power supply. In this way, the already required line for the electrical supply of the filament 7a has a double function for the proposed identification.

Accordingly, it is preferred that the communication device 4 transmits the voltage signal to the control device 6 when a supply voltage for operation of the communication device 4 is applied to the first connection point 3a. It is further preferred that otherwise the communication device 4 omits transmission of the voltage signal.

In relation to the above example with the switching instruction to the lighting device 1a, only the lighting devices 1b and 1d would be supplied with voltage, and consequently only the lighting devices 1b and 1b would transmit a voltage signal to the control device 6 at all. This approach has the advantage that no complicated evaluation in the transmission of the voltage signal is required. Rather, all lighting devices la-h that are actually supplied transmit the voltage signal.

In this connection, it is preferred that after each step, the lighting devices la-h of the lighting structure 2 are polled by the control device 6, preferably in accordance with their identifiers 5, after the voltage signal. Consequently, only the energized and polluted light emitting devices then transmit l ah. If, on the other hand, no query is required for the transmission of the voltage signal, then in this example the lighting device 1a can and will also transmit a voltage signal. However, this is harmless because the control device 6 is already known in any case that the lighting device la is a supply voltage at its first connection station 3a receives. The respective identifier 5 can be used in principle for the addressing of the lighting devices la-h or for any communication with the lighting devices la-h, so that it is also preferred that the control device 6 for transmitting the switching instructions, the lighting devices la-h according to their identifiers 5 addressed.

As can be seen from FIG. 1, the tree-like structure of the illustrated luminous structure 2 is symmetrical, so that it is not possible to distinguish purely from the information of the connections between the luminous devices 1 ah, if not the luminous devices 1 d, e, h the physical positions of the lighting devices lb, c, g are placed and vice versa. However, it may be that, despite symmetry in the tree-like structure as shown, the spatial position of the branch of the lighting devices lb, c, g of that of the branch of the light emitting devices ld, e, h with respect to the spatial orientation of the light emitting devices ld, e, h is different. In this connection, it is preferred that the lighting devices la-h each have an orientation sensor 8, preferably a gravitational acceleration sensor, for determining a spatial orientation of the respective luminous device 1a-h, and that the communication device 4 has the orientation determined by the orientation sensor 8 the respective lighting device la-h transmits to the control device 6. A spatial orientation in this sense is therefore to be understood as meaning a horizontal alignment with respect to a vertical orientation or a diagonal orientation, in each case with respect to the direction of the gravitational force of the earth. A gravitational acceleration sensor allows the determination of the spatial orientation with respect to this direction. This spatial orientation transmitted to the control device 6 can have an arbitrary degree of accuracy, that is to say differentiate only between "substantially horizontally" and "substantially vertically", or else include a specific angle indication. It can also be seen from FIG. 1 that, in contrast to the tree-like structure, a tree structure in the narrower sense would be present if, for example, the lighting devices 1 f and 1 h were each connected only to the luminous device le.

Based on this, it is then further preferred that the lighting devices 1 a-h of the luminous structure 2 are arranged according to the topology in a predetermined spatial orientation and that the control device 6 is assigned to the identifiers 5 also assigns the position based on the transferred spatial orientations. For example, if it is known that the lighting device I b has a substantially horizontal spatial orientation and the lighting device I d has a substantially vertical spatial orientation, then based on this information and the respective transmitted spatial orientation of the branch of the lighting devices lb , c, g are distinguished from the branch of the light emitting devices ld, e, h.

As already mentioned, the given topology can describe a connection configuration of the lighting devices 1 a-h of the lighting structure. Furthermore, the given topology can also describe a three-dimensional spatial orientation of the lighting devices la-h of the lighting structure 2. Such a description may go beyond a purely qualitative distinction of the spatial orientation of two light emitting devices la-h.

Insofar as there are other relevant differences between the individual lighting devices 1 a-h, they too can be used to distinguish otherwise their individual electrical devices 1 a-h or entire branches of lighting devices 1 a-h that are exchangeably arranged. Thus, it is preferred that the light emitting devices are assigned an indication preferably for characterizing a geometry of the respective light emitting device la-h, in particular a length specification, that the communication device 4 transmits the information to the control device 6 and that the control device 6 assigns the identifiers 5 the position also based on the indication. It makes sense, for example, to provide in principle identical built-up lighting devices l a-h in different standard lengths, such as 300mm, 600mm, 900mm, etc. In this way, the flexibility in the spatial arrangement and design of the light assembly 2 is increased. Also, the statement in the above sense can thus - analogous to the above spatial orientation - be used to resolve any ambiguities.

According to the representation of FIG. 2 and as already mentioned, it is preferred that the input voltage provides the electrical energy for operating the luminous element 7a of the respective luminous device 1a-h. Above, a single step of the proposed method has been described, in which a switching instruction has been transmitted to the lighting device la and then voltage signals have been received by the lighting devices 1 b and 1 d. This process can now be repeated, preferably in the following step, a switching instruction is transmitted to one of those lighting devices lb, d, of which previously a voltage signal was received as described. These are here the lighting devices lb, d, which are directly connected to the lighting device la. Thus, a rule for traversing the tree-like structure is used. An arbitrary principle known from the prior art for traversing a tree structure can also be used here, which in principle also causes a tree-like structure to pass through in the present sense. In this case, for example, the additional proviso may come into play that the passage through a circle of the tree-like structure is registered and taken into account accordingly. It is now preferred that these steps be repeated for running through until all identifiers 5 are assigned a position in the topology. This completes the identification process.

As for the communication between the communication device 4 and the control device 6, it is preferable that the communication device 4 wirelessly communicate with the control device 6. Here, in principle, any protocol can be used, in particular, protocols in a frequency range of substantially 2.4 gigahertz have been found to be suitable.

It is further preferred that the identifiers 5 are uniquely assigned to the lighting devices 1 a-h of the lighting structure 2. This means that no identical identifier 5 is assigned to a plurality of lighting devices l a-h.

The tree-like structure shown in Fig. 1 also has a root, which is connected to the first connection point 3a of the lighting device la. The root can be set at a position at which an external voltage source is electrically connected to the lighting structure 2. It is thus preferable that a feed arrangement 9 for providing a supply voltage is electrically connected to the lighting structure 2 at at least one connection point 3a, b of the lighting devices la-h. It is also very important zugt that - as described above - in a first step, a switching instruction is transmitted to an electrically connected to the feed device 9 lighting device 1 ah - so here specifically to the lighting device 1 a.

With regard to a mechanical configuration of the lighting devices 1 ah, it is preferred that the lighting devices la-h are formed substantially oblong with a longitudinal axis and the connecting points 3a, b opposite, preferably at a respective longitudinal end, with respect to the longitudinal axis , This variant also corresponds to the embodiment shown in the figures. The mounting of the luminous structure 2 is then further simplified if, according to a preferred embodiment, the luminous devices 1a-h are constructed mechanically and / or electrically substantially invariably with regard to a directional exchange along the longitudinal axis.

FIG. 2 shows, by way of example, a circuit diagram for such a configuration, in which case the lighting device 1a is shown as representative. It can be seen that an electrical supply to the electrical components of the lighting device la from both connection points 3a, b is ensured by the diodes 10. This also applies regardless of the switching state of the switch 1 1 for switching the input voltage from the - here arbitrarily attached - first connection point 3a to the second connection point 3b. In addition to the above-mentioned communication device 4, the luminous element 7a, the luminous regulator 7b and the orientation sensor 8, the electrical components also comprise a voltage regulator 12 and a microcontroller 13. It can also be seen that according to a preferred embodiment, the connection points 3a, b are bipolar are executed.

An advantageous double function of these connection points 3a, b can be achieved in that the electrical connection points 3a, b also form mechanical connection points for the mechanically detachable connection of the lighting devices 1a-h with one another. As shown in the exemplary embodiment of FIG. 1, it is also preferred that more than two lighting devices la-h are mechanically connectable to one another at a connection point 3a, b. This also results in the electrical connection of more than two light-emitting devices 1 a-h at this connection point 3 a, b.

Claims

claims 1. A method for the identification of electrical lighting devices (l ah) of a lighting structure (2), wherein the lighting devices (l ah), each having two electrical connection points (3a, b), according to a vorzugswei- se predetermined topology releasably mechanically and to the Connection points (3a, b) are electrically connected to the lighting structure (2), wherein the Leuchtvor- directions (l ah) each have a communication device (4) for transmitting the respective lighting device (la-h) associated identifier (5), for receiving a switching instruction and for transmitting a voltage signal in accordance with an input voltage applied to a first connection point (3a), the lighting devices (1 ah) generating an output voltage at a second connection point (3b) based on the received switching instruction, which output voltage as input voltage to those lighting devices (la-h) is applied, with which at the second connection point (3b) is an electrical connection, wherein a control device (6) receives the identifiers of the light-emitting devices (la-h), wherein the control device (6) transmits switching instructions to at least some light-emitting devices (l ah) in several slides, wherein the control device (6) receives a voltage signal from at least one of the lighting devices (la-h) after each step and wherein the control device (6) based on the received voltage signals the labels (5) of the lighting devices (la-h) a Assigns position in the topology. 2. Method according to claim 1, characterized in that the lighting devices (1 ah) can each be switched between a switched-on switching state and a switched-off switching state, wherein in the switched-on switching state the input voltage applied to the first connecting point (3a) as output voltage to the second connection point (3b) is switched through, preferably, wherein in the switched-off switching state, the two connection points (3a, b) are electrically isolated. 3. The method according to claim 1 or 2, characterized in that after each step, the lighting devices (la-h) of the lighting structure (2) of the Kon- troll device (6) preferably according to their identifiers (5) addressed queried after the voltage signal. 4. The method according to any one of claims 1 to 3, characterized in that the control device (6) for transmitting the switching instructions, the lighting devices (l a-h) addressed according to their identifiers. 5. The method according to any one of claims 1 to 4, characterized in that the lighting devices (la-h) each have an alignment sensor (8), preferably a Erdbeschleunigungssensor, for determining a spatial orientation of the respective lighting device (la-h) and that the communication device (4) transmits the spatial orientation, determined by the alignment sensor (8), of the respective lighting device (1 ah) to the control device (6). 6. The method as claimed in claim 5, characterized in that the luminous devices (la-h) of the luminous structure (2) are arranged in a predetermined spatial orientation according to the topology and that the control device (6) corresponds to the identifiers (5 ) also assigns the position based on the transferred spatial orientations. 7. The method according to any one of claims 1 to 6, characterized in that the predetermined topology describes a connection configuration of the lighting devices (la-h) of the lighting structure (2), preferably, that the given topology also a three-dimensional spatial orientation of Luminous devices (1 ah) of the lighting structure (2) describes. 8. The method according to any one of claims 1 to 7, characterized in that the light emitting devices (la-h) is an indication preferably for the identification of a geometry of the respective lighting device (la-h), in particular a length specification assigned, that the communication device (4 ) transmits the indication to the control device (6) and that the control device associates the identifiers (5) with the position also based on the indication. 9. The method according to any one of claims 1 to 8, characterized in that the input voltage, the electrical energy for operating a Leuchtpers- pers (7a) of the respective lighting device (l a-h) provides. 10. The method according to any one of claims 1 to 9, characterized in that the steps are repeated until all identifiers (5) is assigned a position in the topology. 1 1. A method according to any one of claims 1 to 10, characterized in that the communication device (4) with the control device (6) communicates wirelessly. 12. The method according to any one of claims 1 to 1 1. characterized in that the identifiers (5) the lighting devices (l a-h) of the light group (2) are uniquely assigned. 13. The method according to any one of claims 1 to 12, characterized in that a feed arrangement (9) for providing a supply voltage to the lighting assembly (2) at at least one connection point (3a, b) of the lighting devices (l ah) is electrically connected , preferably that in a first step a switching instruction is transmitted to a lighting device (la-h) which is electrically connected to the feed arrangement (9). 14. The method according to any one of claims 1 to 13, characterized in that the lighting devices (la-h) are substantially elongated with a longitudinal axis and the connecting points (3a, b) opposite, preferably at a respective longitudinal end, based on the longitudinal axis are arranged. 15. The method according to claim 14, characterized in that the lighting devices (la-h) are constructed mechanically and / or electrically substantially invariant with respect to a directional exchange along the longitudinal axis. 16. The method according to any one of claims 1 to 15, characterized in that the electrical connection points (3a, b) also mechanical connection points len for the mechanically detachable connection of the lighting devices (l ah) form with each other, preferably that more than two Leuchlvorrichtungen (la-h) at a junction (3a, b) are mechanically connected to each other.