DE102006046167A1 - Lighting unit, particularly rear light, for vehicle, has number of light sources, which are arranged in matrix type and are operated with different lighting levels - Google Patents

Abstract

The lighting unit (1) has multiple light sources, which are arranged in matrix type and are operated with different lighting levels. The multiple light sources with a lighting level continuously and temporarily at the same time another number of sources of light with another lighting level, which are operated continuously for the production of a signal function of the lighting unit. Both the sources of light are arranged in rows (3 to 8). An independent claim is also included for a method for the production of a signal function of a vehicle by a lighting unit, particularly a rear light.

Description

The The invention relates to a light unit, in particular a tail light, for a Vehicle, with a plurality of light sources arranged in a matrix are and are operable with different levels of light. Of Furthermore, the invention also relates to a method for displaying a signal function of a vehicle by means of a light unit.

From the DE 100 11 843 A1 is a motor vehicle lamp with a plurality of light-emitting diodes known, which are arranged like a matrix.

at The known motor vehicle lamp, it is possible, the various light sources to operate with different light levels. This is however only in a limited way Frame possible, that the light sources with a first light level for signaling a first signal function and a second light level for signaling a second signal function are operable.

Therefore It is the object of the present invention to provide a light unit for a vehicle and a method for displaying a signal function of a vehicle to create, with which or which the representation of signal functions more flexible can be.

These The object is achieved by a light unit having the features of claim 1, and a method having the features of claim 10, solved.

A Light unit according to the invention for a vehicle is designed in particular as a tail lamp and includes a plurality of light sources which are arranged like a matrix and with different ones Luminous levels are operable. To represent a signal function by means of the light unit is a first number of light sources with a first light level continuously and a second number of Light sources with a second light level at least temporarily simultaneously continuously operable. This means a signal function is characterized in that at least for a predetermined period of time a first number of light sources having a first light level and simultaneously a second number of light sources with a second one Luminous levels are operable. By this configuration of a light unit Can a single signal function more individual and characteristic can be displayed by simultaneously light a plurality of light units emit with different light levels. Under a matrix-like Arrangement becomes both a strictly vertical and horizontal rows Understood arrangement understood. Furthermore, however, will also Arrangements of light sources understood by which, in horizontal and / or slightly offset from one another in the vertical direction are.

The Light sources are designed in particular as light-emitting diodes and can Also be designed as a multimedia light emitting diodes, each of which designed to generate light beams of different light colors are.

Prefers is the difference between the first luminous level and the second Luminous level greater or equal to a specifiable luminous intensity value. In particular, this difference is designed so that it meets the legal Requirements are sufficient. Preferably, it can be provided that for the representation of a single Signal function the light sources for generating light rays can be operated in the same light color. For example, then be provided that to represent a signal function brake light all light sources for generating light rays with red light color are operable and a first number of light sources light rays in red color with a first light level and a second number of light sources for generating light rays of red color can be operated with a second luminous level.

The first number and the second number of light sources are preferred each arranged in rows. The first and second series of Light sources are each arranged substantially horizontally. These horizontal rows are viewed in the vertical direction arranged consecutively. Thus it can be provided that, for example a first horizontal row, with a first number of light sources, for displaying a signal function with a first light level is operable and arranged thereunder a second horizontal Row, with a second number of light sources, with a second Luminous level is operable.

Thereby can also be generated a signal pattern, which horizontal stripes has, which have different luminous levels.

In corresponding way can the rows, however, also be oriented in particular vertically. Furthermore can be any other spatial direction with regard to the orientation of a Be provided series of light sources. For example, a can also diagonal arrangement of such a series can be provided. As well Is it possible, that the first number of light sources is arranged in an annular manner and the second number of light sources used to generate light rays is operable with a second luminous level, surrounds this ring and / or surrounded by this.

Preferably, at least two first rows and at least two second rows are formed, wel che are arranged in alternating sequence to each other. By this embodiment, a signal function can be displayed, which allows a meandering color representation. This is achieved in that a first row of a first number of light sources emits light signals having a first luminous level and a subsequent second row of a second number of light sources is operable to produce light beams having a second luminous level. Subsequently, in turn, a first row of a first number of light sources is arranged, which in turn emits light beams having a first luminous level, which in turn is followed by a second row of a second number of light sources, which in turn emits light beams having a second luminous level.

Prefers can be provided that at least one light source of the first Number of light sources and / or at least one light source of the second Number of light sources to represent a single signal function with variable light level while the representation of the signal function are operable. For example In this case, a pulsed operation can be provided to the effect that a Light source can be activated and deactivated. Furthermore can also be provided that a pulsating changing the Light levels from a high to a low light level and so on or from a low to a high luminous level and so on is. The diversity and variability the representation of a signal function can thereby be increased again and the characterization of signal functions is further individualized become.

The Design or the visual appearance of the illuminated area of the Light unit can thereby changed in many ways and be customized, in particular for the model care in effortless new characterizing display options given are.

Furthermore It may also be provided that the values of a luminous level during the Representation of a signal function can be changed. So, for example be provided that at a light source, which for representation a signal function with changeable Luminous level is operable, as the first light level is a lower Luminous level and provided as a second light level, a high luminous level is which limits can be changed in the course of pulsating operation are. For example, it may be provided that the high second luminous level is increased as the signal function continues. Corresponding can for the be provided first low value of the luminous level.

Prefers at least two light modules are arranged in each row, which Light modules each comprise a reflector which extends from a horizontal main direction of a light module and thus also one horizontal main direction of the entire light unit upwards or extending downwards, and having at least one light source, which with its main axis at an angle, in particular vertically, to Main direction and the reflector is arranged facing. Prefers is a light module of the first row in relation to the main direction analog formed to a light module of the second row, and in particular symmetrical to the main direction, arranged. This can be a compact light unit be created, which a variety of signal functions in high variability can represent.

Prefers the signal function is a brake light or a tail light or a direction indicator.

Furthermore can be provided that dependent from the activation of individual light sources and / or their individual Luminous level also symbols and figures can be displayed. So, for example Also letters and / or numbers and / or graphic symbols are shown become. For example, you can also arrow symbols for a directional flashing as continuous figures or as pulsating Figures are reproduced.

Essential is that a single signal function through the light sources of a Light unit can be displayed and the light units light with different Emit light levels. The representation of a signal function can also done so that in addition to the first number of light sources, which light rays with emit a first luminous level, and the second number of Light sources, which light rays with a second light level emit, at least a third number of light sources provided is which emit light rays at a third luminous level.

In addition, it can be provided that the light sources of the light unit provided for this purpose are not all activated simultaneously in order to display a signal function, but are switched on successively. For example, it may be provided that initially a first subarea of light sources can be activated to display the signal function tail light, so that, in principle, a light area is generated when the tail light is switched on, which immediately corresponds to the legal minimum requirements with regard to the area size. In addition, subsequently at least a second subarea of light sources can be activated, which then contributes to the representation of the entire signal function tail light. These two subregions then emit light at the same time preferably with different Light levels.

at a method according to the invention a signal function of a vehicle by means of a light unit, in particular tail lamp, arranged with a plurality of matrix-like Light sources which can be operated with different light levels are, visually displayed or displayed. To display the signal function become a first number of light sources with a first light level continuously and at least temporarily at the same time a second Number of light sources with a second light level continuously operated.

advantageous versions the light unit according to the invention are as advantageous embodiments the method according to the invention to watch.

embodiments The invention will be explained in more detail below with reference to schematic drawings. It demonstrate:

1 a sketchy front view of an embodiment of a light unit according to the invention;

2 a plan view of the light unit according to 1 ;

3 a sectional view of the light unit along the section line AA according to 2 ;

4 a schematic sectional view of a light module of a light unit according to the 1 to 3 ;

5 a further embodiment of a light module of a light unit in a sectional view;

6 a partial section of another embodiment of a light module of a light unit in a perspective sectional view;

7 a partial section of another embodiment of a light module of a light unit in a perspective sectional view;

8th a schematic perspective view of another embodiment of a light unit; and

9 a schematic representation of a front view of another embodiment of a light unit according to the invention.

In The figures are the same or functionally identical elements with the provided the same reference numerals.

In 1 is a schematic diagram of a light unit 1 a motor vehicle shown, which is formed in the embodiment as a tail lamp. The light unit 1 includes a cover 2 which the light unit 1 completely covered on the outside. The cover 2 may be a clear glass, which may be tinted, for example.

The light unit 1 In the embodiment, a plurality of light modules, which are arranged like a matrix, comprises. These are several horizontal rows 3 . 4 . 5 . 6 . 7 and 8th formed, in each of which a plurality of light modules are arranged. In the first row 3 are five light modules 31 . 32 . 33 . 34 and 35 arranged. To a horizontal axis are to these light modules 31 to 35 Symmetrical also five light modules 41 . 42 . 43 . 44 and 45 arranged. In addition, in the third row 5 also arranged five unspecified light modules, which in their orientation according to the light modules 31 to 35 the first row 3 are arranged. Five light modules of the third row 5 are positioned so that their row is arranged so as to be offset inwards by a light module. Again symmetrically to the unspecified five light modules of the fourth row 6 arranged. In addition, in the fifth row 7 arranged four unspecified light modules, which according to the light modules 31 to 35 the first row 3 are oriented upwards. Symmetrical again are four unspecified light modules of the sixth row 8th arranged.

In the sketchy representation of the light unit 1 It can also be seen that there are three substantially horizontally extending webs between the respective rows. These symbolize reflectors or reflector elements for the outside of the light unit 1 incident light rays. So is between the rows 3 and 4 a first retroreflective element 9 , between the ranks 5 and 6 a second retroreflective element 10 and between the rows 7 and 8th a third retroreflective element 11 educated.

In 2 is a schematic plan view of the light unit 1 according to 1 shown. In this plan view, it can be seen that the light unit 1 is arcuate and in the exemplary embodiment, viewed in the direction of travel of a vehicle left tail light. In this plan view 2 are the light modules spaced apart from each other 31 to 35 the first row 3 to recognize.

For further explanation of the embodiment of the light unit 1 and in particular the light modules is in 3 a sectional view along the section line AA according to 2 shown. In this 3 It can be seen that the vertically mutually positioned horizontal rows are each offset in the direction of a horizontal module main axis HA. In the embodiment of the light unit shown 1 includes the light module 31 a light source 311 , which is designed as a multi-color LED. The light source 311 is with its main emission direction and thus with the main axis LQA of the light source 311 oriented substantially vertically to this horizontal module main axis HA. In addition, the light module includes 31 a reflector 312 which is hood-shaped and substantially in accordance with a spherical shell segment on the light source 311 extends and preferably extends with its edge regions to the module main axis HA.

In addition, the light module includes 31 a light guide 313 which is formed plate-like and at its the light source 311 opposite side is formed angled. The angled design is the type that the angled portion down and thus in the direction of the light module 41 the second row 4 is oriented. In the sectional illustration shown, it can be seen that the light source 311 in the horizontal direction and thus in the direction of the main module axis HA between the reflector 312 and the light guide 313 located. The light guide 313 extends in the embodiment with a plate-like portion substantially in the longitudinal direction of the main module axis HA.

In an analogous manner to the embodiment of the light module 31 is the light module 41 in the second row 4 formed on the opposite side of the module main axis HA. In essence, this achieves a symmetrical design for the horizontal module main axis HA. Also this light module 41 includes a light source 411 , which with its light source axis LQA in the opposite direction to the light source 311 extends downwards. A reflector 412 is essentially analogous to the reflector 312 formed and a light guide 413 is essentially analogous to the light guide 313 educated. The horizontally slightly offset arrangement of the light module 41 to the light module 31 is still understood in the present example as a symmetrical arrangement. It is particularly preferred that in the embodiment shown, the light modules 31 and 41 form a continuous common overall light module, which is thus on both sides of the main module axis HA analog, in particular symmetrical, is formed. Particularly advantageous may be provided that the light guide 313 and 413 are connected to each other with their respective angled arranged front portions, in particular that these two light-guiding elements 313 and 413 are integrally formed. The entire light guide is then C-shaped in the sectional view shown. Analogously, the light modules are 51 and 61 as well as the light modules 71 and 81 the other rows 5 to 8th educated. Again, the conceptualization is set so that the light modules 51 and 61 form a single common light module. The same applies to the light modules 71 and 81 ,

It can be provided that in each case between the light modules designed as symmetrical overall modules 31 . 41 and 51 . 61 and 71 . 81 one in each 3 only exemplary shown Rückstrahlelement 60 is arranged. As in the illustration according to 3 is shown is this retroreflective element 60 arranged approximately at the height of the respective light sources of the light modules.

In 4 is another sectional view of the entire light module 31 . 41 shown. In this more detailed representation, it can be seen that the light source 311 in a housing module 314 is arranged, which on a carrier part 12 is attached. The carrier part 12 is in the sectional view shown also substantially symmetrical to the horizontal module main axis HA ( 3 ) and has a horizontal U-shape or a C-shape in the sectional view.

Also the light source 411 is in such a housing module 414 arranged, which on the opposite side of the support member 12 is arranged. For positionally stable arrangement of this housing module 314 and the housing module 414 has the carrier part 12 end webs 121 and 122 on which as Anschlungsstege for these housing modules 314 and 414 serve. In addition, it can be seen that the reflector 312 on this case 314 is attached. Analogously, the reflector 412 on the case 414 attached. In addition, the entire in cross section C-shaped light guide 313 . 413 on these housing modules 314 and 414 attached. That the separate light module 31 associated light guide 313 includes a first subarea 313a which is plate-like substantially horizontally between the light source 311 and the cover 2 extends. The same applies to a first subarea 413a of the light module 41 associated light-guiding element 413 , A second subarea 313b is formed angled down and also represents a plate-like portion. In an analogous manner is an angularly arranged second portion 413b of the light-guiding element 413 of the light module 41 arranged angled upwards and in the embodiment shown in one piece with the second portion 313b connected. In this entire light guide 313 . 314 is a retroreflective element 13 arranged integrally. In the exemplary embodiment, this retroreflective element 13 integral in the second subregions 313b and 413b at the carrier part 12 integrated side integrated.

In addition, from the illustration according to 4 to realize that one of the light source 311 facing end surface 313c of the first subarea 313a is formed bevelled. The bevel is designed so that an angle of less than 90 degrees is formed with a horizontally extending axis. The slope and thus the inclination of this area 313c is thus the light source 311 facing. This allows the area in the immediate from the light source 311 emitted light can be coupled, be increased. Similarly, one of the light source 411 facing end surface 413c of the first subarea 413a of the light-guiding element 413 educated.

The reflector 312 is designed in its design and refinement that of the light source 311 emitted light, which at the end surface 313c opposite side on the reflector 312 meets, in general and thus with a high proportion is reflected so that it is in the light guide 313 especially over the end surface 313c can be coupled. The design of the light module is corresponding 41 with regard to a comparable reflective coupling over the end face 413c in the light guide.

In addition, it can also be provided that parts of the surfaces of the subregions 313a and 413a are coated. In particular, the flat surfaces of the sub-area 313a and 413a be vaporized with a metallic layer, which the carrier part 12 are facing.

In 5 is a sectional view of another embodiment of a light module 31 shown. In this embodiment, the light guide 313 shown as an angled element, which has a substantially lying L-shape substantially. As already shown and explained in the preceding figures, by means of such an angled configuration, the photometric surface of the light unit 1 be achieved with regard to legal requirements and a particularly space-optimized concept can be made possible. In the embodiment shown according to 5 are the reflector 312 , the light source 311 and the light guide 313 arranged and formed to each other so that from the light source 311 emitted light before exiting the light unit 1 either at least on the reflector 312 is reflected or in the light guide 313 is coupled. In addition, from the light source 311 emitted light also at the reflector 312 be reflected and then into the light guide 313 be coupled. The arrangement is thus designed so that no emitted light is virtually lost and emitted in an undefined manner. The line L is characterized by the light source 311 emitted light, which just no longer over the end surface 313c in the light guide 313 can be coupled, at least on the reflector 312 meets. Light of the light source 311 is thus always on the reflector 312 reflected and / or in the light guide 313 coupled.

In addition, the bottom is 313d coated. Further, on a surface 313e of the second subarea 313b at least one notch 315 educated. This may in cross-section an arcuate notch and preferably a pointed notch 315 be. The notch 315 is thus on the surface 313e formed, which the cover 2 and thus also the outside of the light unit 1 is facing. In the light guide 313 coupled light can through this notch 315 to step outside and thus increase the brightness of the illuminated surface area. In addition, a light emission can also from the end face 313f of the second subarea 313b respectively.

In 6 is a partial section of another embodiment of a light module 31 shown in a perspective sectional view. In this version, the reflector 312 formed only as a flat, strip-like and curved plate element, which is preferably oriented upwards. The dashed configuration can also be an orientation lying. In addition, with this light module 31 the first row 3 provided that the light guide 313 is formed bracket-like and thus designed in cross-section C-shaped. A symmetrical embodiment of an entire light module to the horizontal module main axis HA according to the embodiments in 3 and 4 is not planned here.

Another embodiment of a light module 31 is as a perspective partial section in sectional view in 7 shown. In this embodiment, in turn, a module main axis HA on both sides at least analog, in particular symmetrical, designed construction is provided. Here are the light modules 31 and 41 again an entire light module. In this embodiment is a light source 311 as well as a light source 411 at the back of the support part 12 arranged. In the emission direction of the light is in front of these light sources 311 and 411 each an optical element 316 respectively. 416 arranged. The optical element may be a lens, a diffraction grating, a prism or the like. In addition, the optical element may also be merely a simple translucent disk. The optical elements 316 and 416 are preferably oriented substantially vertically to the module main axis HA. The optical element 316 is at the Trä gerteil 12 attached and between the light source 311 and the light guide 313 arranged. In addition, this optical element extends 316 to the reflector 312 , In an analogous way, the optical element 416 arranged.

In 8th is a sketchy representation of another embodiment of a light unit 1 shown in perspective. In this embodiment, it can be seen that the reflectors of a row are each overlapped between two reflectors of a row arranged underneath. An alternating sequence of the reflectors and thus also the light modules of two adjacent rows can thereby be achieved in the horizontal viewing direction. In addition, the reflectors are designed in their shape that they are hood-like and have a continuously curved main area, which is closed on opposite sides by vertical surface elements. These can have a vertical front edge area, like the reflector 312 , exhibit. Likewise, these edge regions may also be arc-shaped, as indicated by the dashed lines in the left, in the second row from above, arranged reflector. In addition, a forward sloping design of the edge region may be provided, as indicated in dashed lines in the left reflector of the bottom row.

In 9 is a sketchy representation of another embodiment of a light unit 1 shown, which represents a frontal view.

In this embodiment, the light modules are 31 to 36 the first horizontal row 3 , the light modules 41 to 46 the second horizontal row 4 , the light modules 51 to 56 the third horizontal row 5 , the light modules 61 to 66 the fourth horizontal row 6 and the light modules 71 to 76 the horizontal row 7 strictly symmetrical and arranged like a matrix. In view of the above-described embodiment of these light modules, the associated light sources are thus also positioned strictly symmetrically in horizontal and vertical rows.

The designed as tail lamp light unit 1 is designed to represent multiple signal functions. The light unit 1 can be used both to display a tail light and to display a brake light and also to display a directional flashing.

Based on the signal function tail light, the light unit 1 explained in more detail. If this light function is activated by a vehicle occupant, a successive activation of the light units provided for this purpose follows in chronological order. Thus, it is provided in the exemplary embodiment that initially the light sources of the light modules 71 to 76 and thus the lowest horizontal row 7 be activated and emit light rays with a first light level. In the following then the light sources of the light modules 61 to 66 the horizontal row 6 activated and driven to emit light beams with a second light level.

Again in time then the light sources of the light modules 51 to 56 activated and driven to emit light beams again with a first light level. Subsequently, then, the light sources of the light modules 41 to 46 activated and in turn driven to emit light beams with a second light level. Finally, then the light sources of the light modules 31 to 36 activated and driven to emit light beams with a second light level. In the exemplary embodiment, therefore, all the light sources of the light unit 1 to display the signal function taillight activated, in addition to a first number of light sources, namely the light sources of the light modules 31 to 36 . 51 to 56 and 71 to 76 with a first light level and the light sources of the light modules 41 to 46 and 61 to 66 can be operated simultaneously with a second luminous level. Only when switching on this signal function tail light, the respective light sources are switched one after the other. If all the light sources provided for the representation of this signal function taillight are activated, they light up, as mentioned, with two different light levels. A single signal function is thus represented simultaneously by two different luminous levels. In the exemplary embodiment, a strip structure is thereby produced, wherein strips arranged adjacent to one another have different luminous levels. As a result, the visual impression of a meander-shaped light surface, which alternates between light and dark areas, can be generated.

It can also be provided that at least some of these light modules shown in FIG 9 Have at least two light sources, which are designed to generate light beams of different light color. As a result, a light module can be used simultaneously to display two signal functions. For example, it may be provided that a light module on the one hand is designed to display the signal function tail light and has a first light source which is designed to emit light beams of red light color. In addition, this light module can simultaneously be operable to display a second signal function, for example for displaying a directional flashing, by activating a second light source of this light module for emitting light beams of yellow light color.

In the 9 not shown return elements 13 (for example 4 and 5 ) can then also be used for separation with regard to the representation of at least two signal functions simultaneously. Through these retroreflective elements 13 The legal requirements can then also be met and the required distance for the representation of two signal functions at the same time and thus for the clear recognition of these serve.

Prefers can be provided that between the two levels of light Difference of a luminous intensity value is predetermined, which is at least four candela.

In addition, it can also be provided that, for example, the light sources of the light modules 31 to 36 and 41 to 46 for emitting light beams having a first luminous level and the light sources of the light modules 51 to 56 as well as the light sources of the light modules 61 to 66 for the emission of light beams with a second luminous level can be controlled. In these embodiments, two successive horizontal rows have light emissions with the same luminous levels. Again, this is just another exemplary embodiment and not to be understood in light of the many possibilities of a signal function representation with two different light level ranges simultaneously. In addition to such a striped design, each with different luminous levels, an annular design of such a light surface region with different luminous levels can be provided beyond that. Other symbols or figures which have different luminous level ranges can also be formed.

Claims (10)

Light unit, in particular tail lamp, for a vehicle, having a plurality of light sources ( 311 ; 411 ), which are arranged like a matrix and can be operated with different luminous levels, characterized in that for representing a signal function of the light unit ( 1 ) a first number of light sources ( 311 ; 411 ) with a first light level continuously and at least temporarily simultaneously a second number of light sources ( 311 ; 411 ) are continuously operable with a second luminous level. Light unit according to claim 1, characterized in that the first number and the second number of light sources ( 311 ; 411 ) each in rows ( 3 to 8th ) are arranged. Light unit according to claim 2, characterized in that the first ( 3 to 8th ) and the second row ( 3 to 8th ) are each arranged substantially horizontally and these rows ( 3 to 8th ) are arranged consecutively in the vertical direction. Light unit according to claim 2, characterized in that at least two first rows ( 3 to 8th ) and at least two second rows ( 3 to 8th ) are formed, which are arranged in an alternating order. Light unit according to claim 1, characterized in that at least some of the light sources ( 311 ; 411 ) are designed to generate light signals of different light color. Light unit according to claim 1, characterized in that at least one light source ( 311 ; 411 ) of the first number of light sources ( 311 ; 411 ) and / or at least one light source ( 311 ; 411 ) of the second number of light sources ( 311 ; 411 ) are operable to represent a variable luminance signal function. Light unit according to claim 6, characterized in that the value of the lower light level and / or the value of the upper light level during a pulsed operation of a light source ( 311 ; 411 ) are changeable. Light unit according to claim 2, characterized in that in each row ( 3 to 8th ) at least two light modules ( 31 to 36 ; 41 to 46 ; 51 to 56 ; 61 to 66 ; 71 to 76 ), which light modules ( 31 to 36 ; 41 to 46 ; 51 to 56 ; 61 to 66 ; 71 to 76 ) each have a reflector ( 312 ; 412 ) extending from a horizontal module main axis (HA) of a light module ( 31 to 36 ; 41 to 46 ; 51 to 56 ; 61 to 66 ; 71 to 76 ) extends upward or downward, and at least one light source ( 311 ; 411 ), which with its main axis (LQA) at an angle, in particular vertically, to the main module axis (HA) and the reflector ( 312 ; 412 ) is arranged facing. Light unit according to claim 8, characterized in that a light module ( 31 to 36 ; 41 to 46 ; 51 to 56 ; 61 to 66 ; 71 to 76 ) of the first row ( 3 to 8th ) in relation to the main module axis (HA) analogously, in particular symmetrically, to a Lichttmodul ( 31 to 36 ; 41 to 46 ; 51 to 56 ; 61 to 66 ; 71 to 76 ) of the second row ( 3 to 8th ) is arranged. Method for displaying a signal function of a vehicle by means of a light unit, in particular tail lamp, with a plurality of light sources arranged in a matrix ( 311 ; 411 ), which are operable with different levels of illumination, characterized in that for representing the signal function, a first number of light sources ( 311 ; 411 ) with a first light level continuous Lich and at least temporarily simultaneously a second number of light sources ( 311 ; 411 ) are operated continuously with a second light level.