Controlling a lighting device having at least two electric light sources

Abstract

A method may include supplying electric power to a first light source and a second light source of at least two light sources by at least one ballast so that the first light source and the second light source emit a first source light and a second source light with a first and second spectral light distribution, respectively. The method further includes superimposing the first and second source light using an optical unit such that the lighting device outputs light with a spectral superposition light distribution. The method further includes detecting the light outputted from the lighting device using a light distribution sensor that provides a sensor signal corresponding to a spectral light distribution of the detected light. The method further includes comparing the sensor signal to a predefined spectral light distribution and adjusting the electric power supplied to the respective light source by the ballast based on the comparison.

Claims

1. A method for controlling a lighting device comprising at least two electric light sources, wherein the method comprises: supplying a first electric power to a first light source of the at least two light sources by at least one ballast in order for the first light source of the at least two light sources to emit a first source light with a first spectral light distribution; supplying a second electric power to a second light source of the at least two light sources by the at least one ballast in order for the second light source of the at least two light sources to emit a second source light with a second spectral light distribution different from the first spectral light distribution; superimposing the first source light and the second source light from the at least two light sources by an optical unit of the lighting device such that the lighting device outputs light with a spectral superposition light distribution; detecting at least the light outputted by the lighting device by a light distribution sensor that provides a sensor signal corresponding to a spectral light distribution of the detected light; comparing the sensor signal to a predefined spectral light distribution; ascertaining a respective proportion of at least a first light source and a second light source of the at least two light sources in a light flux of the light output by the lighting device; and adjusting the electric power supplied to the at least the first light source and the second light source of the at least two light sources in a descending order from highest proportion to lowest proportion by the at least one ballast based on the comparison and the ascertained respective proportions of the at least the first light source and the second light source of the at least two light sources.

2. The method according to claim 1, wherein the adjusting the power supplied to the respective light is based on an operating state stability of the respective light source with respect to the spectral light distribution of the source light output by it.

3. The method according to claim 1, wherein the adjusting the power supplied to the respective light source is based on a wavelength of an intensity maximum of the spectral light distribution of the source light output by the respective light source.

4. The method according to claim 1, wherein the adjusting the respective supplied power is based on only a control signal, the amount of which is greater than a predefined minimum value.

5. The method according to claim 1, wherein the adjusting the respective supplied power is based on individual physical characteristics of the respective light source.

6. The method according to claim 1, wherein the detecting of the light output by the lighting device includes detecting at least the light output in an area of an object lighted by the lighting device.

7. The method according to claim 1, wherein the predefined light distribution is based on physical characteristics of the lighted object.

8. The method according to claim 1, wherein the adjusting the powers supplied to the respective light sources is based on a spectral light distribution of the light detected at the lighted object.

9. The method according to claim 1, wherein the light distribution sensor is in communication link with a control device for the lighting device.

10. The method according to claim 1, wherein the light distribution sensor comprises an energy supply unit.

11. The method according to claim 1, wherein the predefined spectral light distribution is based on a spectral light distribution of the at least first spectral light distribution and second spectral light distribution.

12. The method according to claim 11, wherein the at least first spectral light distribution and second spectral light distribution are individually detected at the object to be lighted by the light distribution sensor.

13. The method according to claim 1, wherein the descending order for adjusting the electric power supplied to the at least two light sources occurs based on high wavelength to low wavelengths for the wavelengths of light emitted from the at least two light sources.

14. A control device for controlling a lighting device comprising at least two electric light sources, wherein a first light source of the at least two light sources emits a first source light with a first spectral light distribution based on a supplied first electric power, and a second light source of the at least two light sources emits a second source light with a second spectral light distribution different from the first spectral light distribution based on a supplied second electric power, wherein the first source light and the second source light are superimposed by an optical unit of the lighting device such that the lighting device outputs light with a spectral superposition light distribution, wherein the control device is configured to control at least one ballast of the lighting device such that the first electric power is supplied to the first light source of the at least two light sources and the second electric power is supplied to the second light source of the at least two light sources, wherein the control device comprises: an evaluation unit having a light distribution sensor for detecting at least the light output by the lighting device, wherein the evaluation unit is configured to receive a sensor signal corresponding to a spectral light distribution of the light detected by the light distribution sensor; wherein the evaluation unit is configured to: compare the sensor signal to a predefined spectral light distribution; ascertain a respective proportion of at least a first light source and a second light source of the at least two light sources in a light flux of the light output by the lighting device; provide at least one control signal for the at least one ballast based on the comparison; and adjust the electric power supplied to the at least the first light source and the second light source of the at least two light sources in a descending order by the at least one ballast based on the at least one control signal and the ascertained respective proportions of the at least the first light source and the second light source of the at least two light sources.

15. The lighting device comprising the control device according to claim 14; wherein the lighting device further comprises: the first light source of at least two light sources for emitting a first source light with a first spectral light distribution; the second light source of at least two light sources for emitting a second source light with a second spectral light distribution different from the first spectral light distribution; the at least one ballast configured to supply a first electric power to the first light source of the at least two light sources and configured to supply a second electric power to the second light source of the at least two light sources; and the optical unit configured to superimpose the source light emitted by the at least two light sources such that the lighting device outputs light with a spectral superposition light distribution.

16. The control device according to claim 14, wherein the descending order for adjusting the electric power supplied to the at least two light sources occurs based on high wavelength to low wavelengths for the wavelengths of light emitted from the at least two light sources.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) In the drawings, like reference characters generally refer to the same parts throughout the different views. The drawings are not necessarily to scale, emphasis instead generally being placed upon illustrating the principles of the illumination apparatus. In the following description, various aspects are described with reference to the following drawings, in which:

(2) FIG. 1 is a schematic representation a system overview with objects, which are lighted by lighting devices, wherein light distribution sensors are arranged at the objects and are in communication link with a control device, which in turn is in communication link with the respective lighting devices and the ballasts thereof, respectively,

(3) FIG. 2 is a schematic block diagram of one of the lighting devices according to FIG. 1,

(4) FIG. 3 is a schematic representation a flow diagram for performing a method for controlling a spectral superposition light distribution of light output by the lighting device,

(5) FIG. 4 is a schematic representation a diagram, in which by means of three graphs a respective chromaticity shift of a light emitting diode depending on the operating time is represented by means of three graphs respectively associated with a temperature,

(6) FIG. 5 is a schematic representation of a diagram as FIG. 4, but for a further light source, which is different from the preceding light source according to FIG. 4 with respect to the spectral light distribution of the source light output by the light source,

(7) FIG. 6 is a schematic representation of a diagram, in which a light flux change depending on the time and the temperature is represented for the first light source,

(8) FIG. 7 is a schematic representation as FIG. 6, in which the dependency for the second light source according to FIG. 5 is represented,

(9) FIG. 8 is a schematic bar diagram representation for visualizing a correction strategy for the adjustment of the light sources according to the flow diagram according to FIG. 2, and

(10) FIG. 9 is a schematic diagram representation for representing a typical criterion for S.

DETAILED DESCRIPTION

(11) In FIG. 1, a system overview is shown in a schematic representation, in which a picture is lighted as an object 50 in a left area. In a right area, a group 52 of objects, represented by a picture, is lighted. The object 50 and the group 52 of objects, respectively, is presently respectively lighted by a lighting device 10 and a group 12 of lighting devices, wherein in the group 12 of lighting devices, each of the lighting devices can be formed by a lighting device like the lighting device 10.

(12) The lighting device 10 outputs light 34, which serves for lighting the object 50 and the group 52 of objects, respectively. Correspondingly, each group 12 of lighting devices outputs light 36, which additionally also serves for lighting the object 50 and the group 52 of objects, respectively. In addition, the object 50 is also lighted by ambient light 58, which is presently provided by the sun not labeled.

(13) FIG. 2 exemplarily shows one of the above mentioned lighting devices 10 in a schematic block diagram. In the present embodiment, the lighting device 10 comprises four light sources 14, 16, 18, 20, which emit respective source light 24, 26, 28, 30 due to supply with electric power.

(14) For this purpose, the light sources 14, 16, 18, 20 are each individually connected to a ballast 22, by means of which the respective corresponding electric power can be supplied. Thereby, a respective light flux of the light sources 14, 16, 18, 20 can be adjusted depending on the respectively supplied electric power. Presently, the light sources 14, 16, 18, 20 can be adjusted substantially independently of each other with respect to their light emission.

(15) The light sources 14, 16, 18, 20 output their respective source light 24, 26, 28, 30 with spectral light distributions different from each other. Thus, the light source 14 emits substantially red light, the light source 16 emits substantially green light, the light source 18 emits substantially blue light as well as the light source 20 emits substantially white light. The spectral light distributions are corresponding. The light sources 14, 16, 18, 20 are presently formed by corresponding light emitting diodes.

(16) The source light 24, 26, 28, 30 emitted by the light sources 14, 16, 18, 20 is superimposed by means of an optical unit 32 of the lighting device 10 such that the lighting device 10 outputs the light 34 and the group 12 of lighting devices outputs the light 36, respectively, with a respective spectral superposition light distribution.

(17) The spectral superposition light distribution results from a superposition of the spectral light distributions, which are provided by the source light of the respective light sources 14, 16, 18, 20. The optical unit 32 is presently not further specified. It comprises corresponding suitable optically effective elements like lenses, mirrors, prisms and/or the like to superimpose the respective source light 24, 26, 28, 30 to the respective light 34, 36. Presently, the optical unit 32 further provides a light exit opening for the light 34, which also represents a light exit opening of the lighting device 10 at the same time.

(18) Besides a control unit not further designated, the ballast 22 of the lighting device 10 further includes an evaluation unit 46 as well as a database in the manner of a library 48, in which a plurality of spectral light distributions specified by a user are stored in a storage unit. The above mentioned units are further explained in the following. Moreover, the ballast 22 is connected to an electrical energy supply not further illustrated via an energy supply line 60, via which it is supplied with electrical energy for the intended operation.

(19) From FIG. 1, it is further apparent that a light distribution sensor 38 is arranged in the area of the object 50, here immediately at the object 50. The light distribution sensor 38 serves for detecting the light, which lights the object 50. Besides the light 34, 36, this also includes the ambient light 58. The light distribution sensor 38 thus detects a summary light action from ambient light 58 as well as the light 34, 36 of the lighting devices 10 and the group 12 of lighting devices, respectively.

(20) The light distribution sensor 38 provides a sensor signal 42 corresponding to a spectral light distribution of the light detected by it. Thus, the light distribution sensor 38 is presently arranged distant from the lighting device 10 and the group 12 of lighting devices, respectively. Therefore, it is in communication with the lighting devices 10 and the group 12 of lighting devices, respectively, via a suitable radio link such that the sensor signal 42 can be communicated to the lighting device 10 and to the group 12 of lighting devices, respectively.

(21) Presently, the light distribution sensor 38 comprises an own energy supply unit not illustrated, which allows obtaining electric energy for the intended operation of the light distribution sensor 38 from the detected light at the same time. Thus, in this configuration, the light distribution sensor 38 does not need an external energy supply. In contrast, in other configurations, it can be provided that the light distribution sensor 38 comprises an own electric energy storage like an accumulator, a battery or the like to be able to provide electric energy for the intended operation. Moreover, there is of course also the possibility of connecting the light distribution sensor 38 to an energy supply network, for example to the energy supply network 60, to which the ballast 22 is also connected.

(22) From FIG. 2, it is apparent that the ballast 22 includes a control device 54, which includes both the evaluation unit 46 and the library 48. Moreover, the control device 54 includes a communication unit 62, which is formed to receive and evaluate the sensor signal 42 emitted by the light distribution sensor 38 via radio. For this purpose, the evaluation unit 46 includes a comparison unit not further illustrated, which ascertains a detected light distribution from the sensor signal 42 and compares it to a predefined spectral light distribution, which is ascertained from one of the spectral light distributions specified by the user as will be explained in the following. Depending on the comparison, a control signal for the ballast 22 is provided, which serves to be able to adjust the electric power supplied to the respective light sources 14, 16, 18, 20. Thereby, it is possible to also be able to adjust the spectral superposition light distribution of the light 34 and 36, respectively.

(23) The light distribution sensor 38 is formed to ascertain the spectral light distribution of the detected light. For this purpose, the light distribution sensor 38 can include one or more photodetectors, for example photodiodes or the like, which are preferably sensitive to different predefined ranges of the light spectrum. Corresponding to the detected light distribution and preferably considering the detected light flux, the sensor signal 42 is provided.

(24) In the right area of FIG. 1, a corresponding representation for the group 52 of objects is provided. Corresponding to the group 52 of objects, a group 40 of light distribution sensors is also provided, wherein each one of the light distribution sensors of the group 40 is preferably arranged in the area of one of the objects of the group 52 of objects. Each of the light distribution sensors of the group 40 corresponds to the light distribution sensor 38 with respect to its functionality. The group 40 of the light distribution sensors is in communication link with each othernot further illustrated. The spectral light distributions correspondingly detected by the group 40 of the light distribution sensors, are communicated via a communication link 158, which is presently also a radio link, as previously described, to the lighting device 10 and the group 12 of lighting devices, respectively. Correspondingly, the lighting is adjusted and controlled by light output of the light 34 and 36, respectively. The further details correspond to what was already previously explained.

(25) In FIG. 1, the control device 54 is represented as a separate unit separated from the light distribution sensors 38 and the group 40 of the light distribution sensors, respectively, and the lighting device 10 and the group 12 of the lighting devices, respectively. However, the control device 54 can be arranged at least partially integrated in one of the above mentioned units or devices. From FIG. 1, it is further apparent that the control device 54 is immediately in communication link with the light distribution sensor 38 as well as the group 40 of light distribution sensors. In this case, an immediate communication link with the lighting device 10 and the group 12 of lighting devices, respectively, does not have to exist from the light distribution sensor 38 and the group 40 of light distribution sensors, respectively. The lighting device 10 and the group 12 of lighting devices, respectively immediately obtain their respective control signals as control signals 56 from the control device 54. If the control device 54 is arranged spatially separated from the lighting device 10 and the group 12 of lighting devices, the communication link with the control device 54 can also be a radio-based communication link, via which the respective control signal 56 can be communicated. In non-limiting embodiments, the communication link is bidirectional such that control signals cannot only be communicated from the control device 54 to the lighting device 10 and the group 12 of lighting devices, respectively, but data can conversely also be communicated from the lighting device 10 and the group 12 of lighting devices, respectively, to the control device 54, for example parameters with respect to a functionality, malfunction messages, operating state messages and/or the like.

(26) Further, the control device 54 is formed to enter in communication link with a programming appliance 66 via a presently also wireless communication link 64. Presently, the programming appliance 66 is formed by a portable computer unit, for example a laptop or the like. Presently, the communication link 64 is based on short-range radio, for example based on a WLAN standard or the like. Alternatively, an ultrasonic-based communication link or an infrared-based communication link can also be provided here. The control device 54 can be adequately programmed by the programming appliance 66. In particular, the predefined spectral light distribution can be adjusted or one of the spectral light distributions specified by the user can be selected from the library 48. Moreover, a series of further parameters can also be adjusted, for example a dependency of the predefined spectral light distribution on an ambient temperature, which can be detected by means of a non-illustrated temperature sensor, and/or the like.

(27) Moreover, the control device 54 is formed to enter into communication link with communication terminals 70, such as for example a smart phone or the like, via a further communication link 68. Here too, the communication link 68 can be formed by a short-range radio link or the like. For example, user-specific parameters can be adequately adjusted by the communication terminal 70, for example in that a user is able to communicate a desired light intensity to the control device 54, such that the lighting device 10 and the group 12 of lighting devices, respectively, output their light 34, 36 such that the desired lighting effect of the object 50 and the group 52 of objects, respectively, can be achieved. Thus, the user can for example adjust different lighting scenarios to be able to view the object in different lighting scenarios. For example, it can be provided that the user adjusts a lighting as by daylight at midday in a first adjustment, whereas he can be capable of adjusting a lighting by daylight as at dusk or at dawn in a second adjustment. Thereby, high user friendliness in particular with respect to the lighting of the object 50 and the group 52 of objects, respectively, can be achieved.

(28) In the following, an adjustment of the lighting device 10, as it has been explained based on FIG. 1, is to be further detailed based on the flow diagram illustrated in FIG. 3. The method begins in step 72, which represents the start of the method. From the start position in step 72, the procedure is continued with a step 76. In step 76, the control device 54 receives the sensor signal 42 and 44, respectively, of the light distribution sensor 38 and the group 40 of light distribution sensors, respectively, the sensor signal 42 and 44, respectively, of which corresponds to a spectral light distribution of the respective detected light of the light distribution sensor 38 and the group 40 of light distribution sensors, respectively.

(29) In a next step 78, it is examined if an amount of a difference of the detected spectral light distribution to a predefined spectral light distribution is less than a predefined minimum value. If the amount of the difference is less, this is denoted by y, a branch to step 90 is effected, which defines the end of the adjustment. The procedure is terminated at this place.

(30) In contrast, if the difference is greater, a branch is effected, which is denoted by n. The method is then continued with step 80 in the following.

(31) In step 80, an individual channel calibration for each of the light sources 14, 16, 18, 20 is executed as it will be further detailed in the following based on FIG. 8. Presently, it is provided that a predefined number of x %steps is performed for the light sources 14, 16, 18, 20. In the following, this is denoted by S.sub.i(x), wherein the index i stands for the respective one of the light sources 14, 16, 18, 20. x indicates the percentage.

(32) Then, the method is continued in a step 82. In step 82, calculation of electric parameters is effected, which serve to associate corresponding powers, which are supplied from the ballast 22 to the respective light sources 14, 16, 18, 20 as the electric power, corresponding to the previously ascertained light fluxes S.sub.i(x). The respective electric powers are denoted by P.sub.i(I) in the following.

(33) In the following step 84, the electric parameters P.sub.i(I) are sorted in descending order of their contribution to the entire spectral light distribution. Hereby, an order results, according to which the light sources 14, 16, 18, 20 are adjusted in the further course. This first relates to the light sources, which output white light, thus here the light source 20.

(34) In the next step 86, the non-white or colored light sources are adjusted. This presently relates to the light sources 14, 16, 18. In this step, sorting of the corresponding electric parameters in descending order from a large wavelength to smaller values of is effected. Thus, an order of P.sub.R(I) . . . P.sub.G(I) . . . P.sub.B(I) for example results, wherein R stands for red, G for green and B for blue.

(35) In the following step 88, the powers to be supplied to the light sources 14, 16, 18, 20 are adjusted according to the electric parameters, as they were previously ascertained. Hereafter, the method jumps to an insertion point 74 and the method is continued with step 76.

(36) Therein, the procedure is repeated until it is determined in step 78 that the amount of the difference falls below the tolerance or the minimum value.

(37) With FIGS. 4 and 5, two schematic diagrams 92, 94 are illustrated, by which a color location shift depending on a temperature and an operating time of two different light sources, presently two different light emitting diodes, is represented. In the diagrams, the abscissa 96 denotes a time axis, on which the time in hours is indicated. Ordinates 98 of the diagrams 92, 94 indicate a relative color deviation.

(38) In FIG. 4, a color location shift depending on the operating time of the light emitting diode at a temperature of 55 C. is indicated with a graph 100 in the diagram 92. With a graph 102, a dependency on the operating time at a temperature of 85 C. is represented. Correspondingly, a graph 104 represents the dependency on the operating time at a temperature of 118 C. It is apparent that a relative color deviation slowly increases with increasing operating time at the temperature von 55 C. The further graphs 102 and 104 show that the higher the temperature is, the relative color deviation considerably faster increases and also predominates in its magnitude as it is apparent based on the graphs 102 and 104. Presently, this is represented for a red light emitting diode.

(39) FIG. 5 shows comparable conditions for a blue light emitting diode. The dependency over the operating time at a temperature of 55 C. is again represented by a graph 106, whereas the graph 108 represents a dependency on the operating time at a temperature of 85 C. and the graph 110 represents the dependency on the operating time at a temperature of 115 C. It is apparent that the relative color location shift is considerably less with respect to the red light emitting diode according to FIG. 4, namely also with increasing operating time. In FIG. 5, a limit value is represented by the straight line 112, which is predefined by an Energy Star standard.

(40) This demonstrates how variations of the spectral superposition light distribution of the light 34, 36 output by the lighting device 10 and the group 12 of lighting devices, respectively, occur with increasing operating time of the lighting device 10 and the group 12 of lighting devices, respectively. Non-limiting embodiments address this problem and counteracts this development by a feedback in the manner of a control such that the impacts of variations of the spectral superposition light distribution can be overall considerably reduced, if not even completely prevented, over the entire operating time of the lighting device 10 and the group 12 of lighting devices, respectively.

(41) With diagrams 116, 118 in FIGS. 6 and 7, a corresponding variation of the relative light flux of the light emitting diodes, as they were already taken as a basis for the discussion to FIGS. 4 and 5, is represented. A respective abscissa 96 again denotes the time, which is indicated in hours on the respective abscissas. A respective ordinate 114 in the diagrams 116, 118 denotes a relative variation of the light flux in percent.

(42) From the diagram 116 of FIG. 6, which is associated with the red light emitting diode, which was already explained according to the diagram 92 according to FIG. 4, the relative variation of the light flux over the operating time of the light emitting diode at a temperature of 55 C. is represented with a graph 122. With a graph 124, the same variation is represented for a temperature of 85 C. and the corresponding variation at a temperature of 115 C. is represented with a graph 126. It is apparent that a relative decrease of the light flux is not only effected with increasing operating time of the light emitting diode, but moreover is also dependent on the temperature. Thus, the relative decrease of the light flux additionally increases with increasing temperature. Limit values are indicated with the graphs 128 and 130, which result from the Energy Star standard, namely with the graph 128 for an operating time of up to 35,000 hours, and with the graph 130 for an operating time of up to 25,000 hours. A limit value is represented with a straight line 120, which is not to be undershot by a light flux of the light emitting diode.

(43) FIG. 7 shows a corresponding diagram as FIG. 6, but wherein here the abscissa 96 representing the time axis includes a greater time scale due to the considerably higher operating stability of the blue light emitting diode with respect to the red light emitting diode according to FIG. 6, wherefore it is presently logarithmically configured. Here too, a limit value is represented with a straight line 120, which is not to be undershot by a light flux of the light emitting diode. The dependency of the relative light flux on the operating time at a temperature of 55 C. is represented with a graph 132. Correspondingly, the graphs 134 and 136, respectively, represent the conditions at a temperature of 85 C. and 118 C., respectively. With the graphs 138, 140 and 142, extrapolated developments are represented. Therein, the graph 138 is associated with an operating temperature of 55 C., the graph 140 is associated with an operating temperature of 85 C. and the graph 142 is associated with an operating temperature of 118 C.

(44) From the diagram 118 according to FIG. 7, it is apparent that the relative variations of the light flux depending on the operating time and the temperature are considerably lower in the time scale as it is represented in the diagram 116 of FIG. 6. Thereby, the lower influence on the variation of the spectral superposition light distribution of the lighting device 10 and the group 12 of lighting devices, respectively, also explains.

(45) FIG. 8 shows in a schematic bar diagram 144, how the adjustment according to the flow diagram of FIG. 3 practically operates. It is apparent that a proportion in the light flux of the white light source 20 is represented by the bar 1, whereas a bar for a light flux proportion of the red light source 14 is denoted by 2, a bar for a light flux proportion of the green light source 16 is denoted by 3 and a bar for a light flux proportion of the blue light source 18 is denoted by 4. From it, the order of the adjustment of the light sources 20, 14, 16, 18 in this order also results at the same time.

(46) FIG. 9 shows a further schematic diagram 146, which represents the application of the algorithm. An abscissa 148 is associated with a coordinate vector e1, whereas an ordinate 150 is associated with a coordinate vector e2.

(47) For example, if one selects

(48) $\begin{matrix} S = {.Math.}_{k = 1}^{n} {(100 - Ri)}^{2} & (6) \end{matrix}$
as the quality criterion, a typical progression manifests for S, as it is represented for a good color reproduction by the graph 154 and for a poor color reproduction by the graph 152. The crest-like profile of this quality criterion is presently characterized in that a severe gradient in S can be observed transversely to the crest, while it is weak longitudinally to the crest. Thereby, the ascertainment of an absolute best value can possibly not be unique such that further criteria are required for the determination of the final operating point, for example a proximity to operating points with a similar color temperature or the like.

(49) Presently, it manifests that S is substantially dependent on a proportion, which describes cold white light and shows a very flat behavior with respect to the other degree of freedom in the plane. The progression of S is smooth. This simplifies finding any optimum with respect to this criterion, but wherein further criteria are also required to localize the location of the optimum in reproducible manner.

(50) The system construction according to FIG. 1 further includes that the lighting device 10 and the group 12 of the lighting devices, respectively, is oriented with respect to the respective object 50 and the group 52 of objects, respectively, such that they are covered or lighted by the light 34, 36 respectively output by the lighting device 10 and the group 12 of lighting devices, respectively. In the present configurations, it is in particular to be noted that not only the light 34 and 36, respectively, is detected, but also further light, which is output by the environment and contributes to the lighting of the object 50 and the group 52 of objects, respectively, by the light distribution sensor 38 and the group 40 of light distribution sensors, respectively. This is indicated by the ambient light 58 in FIG. 1. The ambient light 58 can include both natural radiation such as daylight, which for example enters through a window, and artificial lighting, for example by foreign lighting devices. Therein, the light distribution sensor 38 and the group 40 of light distribution sensors, respectively, detect the light impinging on the object 50 and the group 52 of objects, respectively, with its entire spectral distribution as a sum, namely preferably in the spectral sensitivity range of the light distribution sensor 38 and the group 40 of light distribution sensors, respectively, thus for example in the visible light range, in the UV range and preferably also in the IR range. In addition, the respective illuminance can in particular also be detected, for example considering the V() curve defined for the human eye, or according to other evaluation functions for calculating defined parameters, for example with respect to the plant growth or the like.

(51) By the overall system represented in FIG. 1, a closed loop circuit can be provided. The communication links can be effected by means of wired communication links, for example based on an USB interface protocol, Ethernet or the like, or also based on a wireless communication link, such as for example radio, WLAN, ZigBee, Bluetooth or other suitable communication protocols, such as for example based on infrared, visible light like LiFi or the like.

(52) The light distribution sensor 38 and the group 40 of light distribution sensors, respectively, can be supplied with electric energy by a wired communication channel or also in battery-assisted manner. Moreover, there is also the possibility of utilizing temperature fluctuations and/or solar cells to generate electric energy, or the like. The communication is preferably effected until the desired spectral light distribution has been achieved with sufficient accuracy.

(53) Therein, for analysis in operation monitoring described in the following, in a further step, evaluation analyses such as for example color location, color reproduction, color temperature, distance from the Planckian locus and/or other quality features as well as for example illuminance and the extrapolated annual dose can be ascertained and/or calculated. Therein, it can be advantageous if the light distribution sensor is arranged immediately at the object and detects all of the radiation impinging on the object. In non-limiting embodiments, all of the values are stored and can be readable upon later communicative coupling to an evaluation system.

(54) If multiple lighting devices are combined to a lamp group, the individual lighting devices can be individually calibrated to be able to uniquely associate a light source in an ascertained spectrum. Therein, it can be advantageous if natural daylight is not present on the one hand, whereby the measurement can preferably be performed at night, in particular in time-controlled manner, and only the lighting device to be calibrated is in operation on the other hand. All of the lighting devices associated with the group can then be calibrated one after the other.

(55) A determination of comparative values, in particular the minimum value, as well as also operating states, can be wirelessly performed by means of suitable control signals by the programming appliance 66 and/or also by communication terminals 70. Therein, the consideration can take into account the compliance with target values, which consider the current spectral light distribution of the lighting devices at the measurement point of time or which are extrapolated in a selectable operating mode based on operating hours into the future, the integrated spectral light distribution over a period of time.

(56) As previously explained, a set value in the form of a predefined spectral light distribution or in the form of quality parameters can be described (CRI, CQS, TM-30, (x;y), (u;v), spectral distribution, color temperature T.sub.F and/or the like). The control device 54, which can also be part of the light distribution sensor 38 in a particular characteristic, ascertains a deviation from the set value and calculates the correction values based on the above described procedure from the found deviation.

(57) The light distribution sensor 38 transmits the sensor signal 42, 44 with respect to the manipulated parameters influencable in the lighting device 10, for example dimming channels R, G, B, A, WW, CW, to the associated lighting device 10. It processes the sensor signal 42, 44 and adapts its spectral superposition light distribution based on the new values for the different dimming channels. The cycle with respect to the set valueactual value comparison with corresponding communications for correction repeats until the desired result is achieved and the deviation from the set value is below the previously determined threshold value or the minimum value. A sufficiently low deviation from the set value can be satisfied if the color location of the detected spectral light distribution is within n McAdam ellipses around the color location of the set spectrum or the sum of individual deviations of set and actual spectrum assumes a minimum. In case of failure, a message can be output to a central control unit or also to the programming appliance 66 or the communication terminals 70.

(58) The calibration and operation monitoring, respectively, can preferably be performed permanently or also in suitable time intervals for first configuration, for example daily, weekly, monthly and/or freely configurable.

(59) With respect to the predefinable spectral light distribution, a suitable spectral light distribution can be selected from the library 48, in particular if calculated spectral light distributions are not present, which preferably includes predefined spectral light distributions correspondingly suitable for the application, which are there retrievably stored. The library 48 can be extended by calculated spectral light distributions, for example by means of the programming appliance 66 or also the communication terminals 70.

(60) In non-limiting embodiments, at least two controls can basically be performed, namely firstly the control of a radiation quality. The permanent correction of possible deviations from the detected spectral light distribution of the lighting device to the set spectrum can be adapted to a desired pattern. Moreover, the radiation quantity can secondly be controlled. The compliance with lighting predefinitions can be realized upon exceeding or falling below threshold values. The illuminance can be controlled to a desired value. Therein, it can be continuously readjusted and maintenance works by color location variations or light flux deviations can be reduced or are no longer required.

(61) With respect to the radiation quantity, for the protection of lighted objects, an annual dose predicted based on utilization profiles can be used for preserving artworks in museums or galleries. Herein, user profiles can be calculated, namely based on turn-on durations of the lighting device 10. With the measured spectral light distribution at the object and the user profiles, it can be calculated, which annual dose would load the object with unchanged adjustment. In case of threshold value exceedance, measures can be derived from it by means of the control device 54, such as for example dimming the lighting device 10 and the light sources 14, 16, 18, 20 thereof, respectively, or also turning off the associated lighting device 10 and group 12 of lighting devices, respectively. Optionally, alarm signals can be configured such that warning messages can be output to preconfigured receivers or mobile communication terminals upon exceedance or shortfall. Shortsfalls can be critical if the lighting is for example employed for growth promotion of organisms, for example plants, algal or the like. Herein, both compliance with the radiation quantity and the radiation quality, such as for example maintenance of growth promoting spectral light distributions, are advantageous. Further fields of application are compliance with certain industry standards, such as for example an illuminance in a museum conservation, compliance with the TLCI standard in the movie and television industry and/or the like.

(62) Moreover, the light distribution sensors can additionally also be used to for example be able to detect a presence of persons and thus to reduce the artificial lighting upon absence of persons to protect sensitive objects on the one hand, or to ascertain, which objects get the greatest interest of persons on the other hand.

(63) Finally, there is also the possibility that the light distribution sensors contain so-called beacons. They can communicate information to mobile communication terminals, which are in the range of the objects. This information can include information with respect to the respective object or also provide information, which provide more in-depth further information to the object in an intranet or in the Internet. In an example, it is conceivable that a viewer standing in front of a picture obtains audio or video files, which for example relate to an artist, relate to the picture content, in particular with respect to the origination, or further information associated therewith.

(64) In non-limiting embodiments, the automated adjustment of the predefined spectral light distributions and monitoring or maintaining them constant over time for the purpose of the maintenance of lighting equipments with multiple, variable light generating circuits, the aging characteristics of which differ from each other. A further advantage is the protection of sensitive objects by dimming or turning off upon too high loads and alerting the monitoring systems. Maintenance works for lighting devices with high demand to the light quality or light quantity can be reduced or even be omitted.

LIST OF REFERENCE CHARACTERS

(65) 1 bar

(66) 2 bar

(67) 3 bar

(68) 4 bar

(69) 10 lighting device

(70) 12 group of lighting devices

(71) 14 red light source

(72) 16 green light source

(73) 18 blue light source

(74) 20 white light source

(75) 22 ballast

(76) 24 source light

(77) 26 source light

(78) 28 source light

(79) 30 source light

(80) 32 optical unit

(81) 34 light

(82) 36 light

(83) 38 light distribution sensor

(84) 40 group of light distribution sensors

(85) 42 sensor signal

(86) 44 sensor signal

(87) 46 evaluation unit

(88) 48 library

(89) 50 object

(90) 52 group of objects

(91) 54 control device

(92) 56 control signal

(93) 58 ambient light

(94) 60 energy supply line

(95) 62 communication unit

(96) 64 communication link

(97) 66 programming appliance

(98) 68 communication link

(99) 70 communication terminal

(100) 72 step

(101) 74 insertion point

(102) 76 step

(103) 78 step

(104) 80 step

(105) 82 step

(106) 84 step

(107) 86 step

(108) 88 step

(109) 90 step

(110) 92 diagram

(111) 94 diagram

(112) 96 abscissa

(113) 98 ordinate

(114) 100 graph

(115) 102 graph

(116) 104 graph

(117) 106 graph

(118) 108 graph

(119) 110 graph

(120) 112 straight line

(121) 114 ordinate

(122) 116 diagram

(123) 118 diagram

(124) 120 straight line

(125) 122 graph

(126) 124 graph

(127) 126 graph

(128) 128 graph

(129) 130 graph

(130) 132 graph

(131) 134 graph

(132) 136 graph

(133) 138 graph

(134) 140 graph

(135) 142 graph

(136) 144 bar diagram

(137) 146 diagram

(138) 148 abscissa

(139) 150 ordinate

(140) 152 graph

(141) 154 graph

(142) 158 communication link

Controlling a lighting device having at least two electric light sources

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Inventors

Cpc classification

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G01J5/60

PHYSICS

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H05B47/19

ELECTRICITY

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H05B45/20

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H05B45/37

ELECTRICITY

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G09F19/205

PHYSICS

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Y02B20/40

GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS

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H05B45/22

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H05B47/16

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H05B45/10

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G01J3/465

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H05B47/10

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H05B47/19

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H05B45/50

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G01J5/60

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H05B47/16

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H05B45/20

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H05B45/22

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G01J3/46

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H05B45/10

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G09F19/20

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Abstract

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Description