WO2017050756A1 - Light device including a light source comprising rods with zones of different colours - Google Patents

Abstract

The invention relates to a light device for a vehicle, comprising: a light source comprising sub-millimetre electroluminescent rods, all of said rods being divided into multiple different lighting zones (1 to 3), at least one lighting zone being arranged such as to emit a colour different from that emitted by at least one other lighting zone; and at least one lens which can receive the light rays emitted by the lighting zones and deflect said rays away from the light device, the light source and the lens being arranged such as to form a light beam and such that multiple different colours can be imparted to this light beam.

Description

 LUMINOUS DEVICE COMPRISING A LIGHT SOURCE WITH STICKS WITH DIFFERENT COLOR ZONES

The present invention relates to the field of vehicle light devices emitting light beams comprising several parts.

 It is known vehicle lighting devices generating light beams of road lighting. A light beam of this type is generally of a single color, for example white, red or amber. Some of these beams nevertheless have irregularities, such as a separation of colors at the cut-offs of the dipped beam. These colors are perceived as anomalies, also the state of the art includes different solutions to avoid or compensate for this separation of color.

 It is also consistent to seek to improve the perception of these beams or the effectiveness of these.

 In the context of lighting beams, the evolution of the technique aims constantly to improve the perception of the driver of the road. This perception is improved in particular by using more powerful, more homogeneous, and / or wider lighting. Other improvements have also focused on how to make cuts, for example by making clean cuts, without being too marked, however, so as not to interfere with the driver.

 Also, certain technical solutions aim to improve the perception of light beams by people outside the vehicle, including the perception of beams emitted by signaling devices, such as rear lights.

A problem addressed by the present invention is therefore to further improve the night perception allowed by the light beams emitted by the light devices of a vehicle, both for the driver and by persons outside the vehicle.

 The Applicant has found that by using beams of light with different colored parts, the perception for the driver was greatly improved.

 Also a first object of the present invention is a vehicle light device comprising:

 a semiconductor light source comprising a plurality of electroluminescent rods of submillimetric dimensions, all of these rods being distributed in several distinct light zones, at least one light zone being arranged in such a way as to emit light rays of a color different from that of the light rays emitted by at least one other light zone,

 at least one shaping optics adapted to receive the light rays emitted by the light areas and to deflect them out of the light device,

the light source and the shaping optics being arranged to form a light beam and to be able to give this light beam several different colors.

 By "giving this light beam several different colors" means that:

 the beam may comprise different parts of different colors, and / or

 - The beam is one color at a time but this color is suitable for modification.

 Thus, the device makes it possible to obtain a light beam:

- illuminating different areas of the road with different colors, to improve the perception of the environment of the road, and / or - Having a uniform overall color but can be changed, for example according to the choice of the user or a calculator;

 having a different color depending on where it is observed, allowing a better representation of the position of the vehicle or achieving a different visual signature, and / or

 presenting an appearance with different colorations, achieving a particular visual signature.

The invention has the advantage of allowing the production of such beams using a single light source, through the use of a semi ^¬ conductor source comprising a plurality of electroluminescent strips submillimeter dimensions.

 A single connector can be used by directly connecting this light source to the power supply. This results in savings in terms of the number of light sources, connections, and electrical harnesses.

 A semiconductor light source comprising a plurality of submillimeter-sized electroluminescent rods will be referred to as a rod light source in the remainder of the application.

 The invention also takes advantage of the light emitting semiconductor light source, distributing all of its rods in several light areas, able to emit different colors.

Note that according to one embodiment of the invention the color of at least a portion of the beam is adjustable. For example, this adjustment can be done by electrically activating or not different light areas to vary the size and / or shape of the portion of the beam of a given color. It is also possible to arrange the shaping optics to mix the colors of the light areas, so that the rays emitted by certain light areas of a given set, while mixing, are deflected by the optics formatting so as to achieve a part of the beam of a given color, corresponding to the mixture of these rays there. By activating or not certain areas of the given set, the color and / or shape of the corresponding part can be adjusted.

 The light device according to the invention may optionally include one or more of the following characteristics:

 the rods have a thickness of between 0.1 and 2 μm, in particular between 1.4 and 1.6; this makes it possible to increase the light emitting surface and confers more brightness to the light source;

 the rods have for example a height of between 2 and 3 μm; this makes it possible to increase the light emitting surface and confers more brightness to the light source;

 the rods are separated from each other by a distance between 1 and 35 μm, preferably between 3 and 30 μm, preferably between 20 and 30 μm;

the maximum of distance corresponds to a minimum of density in sticks; although this maximum distance is not limiting, it gives better results in terms of brightness, especially for a car lighting device; the minimum of 1 pm allows easier realization of these light sources, in particular the growth of rods; nevertheless, when the sticks are too dense, the emission of certain sticks may be hindered by the presence of other sticks, which screen it; the efficiency of the light source is significantly improved with a distance of at least 3 μm; the yield reaches a particularly interesting value with a distance of at least 20 μm;

the optimal interval, in terms of compromise with respect to performance and brightness, is between 20 to 30pm; this interval is however not limiting;

 the rods extend from a substrate, especially in a preferred direction;

 the rods comprise a metal nitride, in particular a gallium nitride, and / or the substrate is essentially based on silicon; nitrides of metal and in particular gallium make it possible to obtain good results in terms of light emission; Silicon makes it possible to produce a light source, and therefore a light device, which is less expensive than conventional LEDs;

 the light source is arranged so that said light areas are selectively activatable; and the light areas are able to be supplied with electricity independently of each other and said rods of the same light zone are electrically powered when the light zone is electrically powered; the different light zones are thus able to be controlled independently, in particular to vary the shape of the portions of the beam of different colors and / or their colors, or even so as to give the light beam a single color but while being able to change the -this ;

the light source comprises connection means intended to be connected to a power supply, this connection means being arranged to supply electrically and independently the different light areas; source luminaire can thus receive the power supply of the different zones from a single point of connection;

 the substrate comprises a cathode connected to or forming a negative pole of said connection means; it is a simple connection of the light source;

 the light source comprises at least as many anodes as light areas, each anode being arranged to be in contact with each of the rods of one and the same light zone, in particular each anode being connected to one or more positive terminals of the light source; connecting means or each forming a positive terminal of the connection means; This is a compact and simple example of the connection of each light zone, compactness all the more improved when the anodes are connected to the same connection means;

 each anode is formed by a conductive layer deposited on top of the substrate, on the rod side, and electrically joining the rods to each other; it is an example of a more compact embodiment of the light source;

 the luminous device comprises a control means of the different light zones arranged to independently supply the light areas according to a received control signal; thus this control means is included directly in the light device, without it being necessary to adapt the support or the global device that receives it;

the light source comprises a layer of a luminophore arranged above the rods so that the phosphor receives the rays emitted by the rods and in turn emits light rays, corresponding to the light rays emitted by the corresponding light zone, and the control means is adapted to adjust a power supply modulated in voltage of at least two light zones, in particular by adjusting the average voltage value and the maximum voltage amplitude value differently in these two light zones, so that the colors emitted by these two light areas are different; alternatively, the power supply can be modulated in current, instead of being modulated in voltage, in particular by adjusting the average current value and the maximum current amplitude value differently in these two light zones, so that that the colors emitted by these two luminous zones are different;

 the chemical composition of the rods of at least one light zone differs from the chemical composition of the rods of at least one other light zone, so that the rods of the at least one light zone emit light rays of a a color different from that of the light rays emitted by the rods of the at least one other light zone;

 each light zone comprises a layer of a luminophore arranged above the rods so that the phosphor receives the rays emitted by the rods and in turn emits light rays, corresponding to the light rays emitted by the corresponding luminous zone, at least two light zones differing from each other by:

 o the chemical composition of their rods, o the chemical composition of their phosphor layer, and / or

 the thickness of their phosphor layer;

the light zones are distributed in a light group, each of these groups comprising at least two light zones, in particular arranged in an adjacent manner, and for each of the light groups, each light zone being able to emit light rays a color different from that of the light rays that other light areas of this light group are able to emit; it is an embodiment in which a finer discretization of the light source is obtained; to further improve the discretization, the shaping optics is arranged so that the areas illuminated by each light zone of the same group overlap and are substantially superimposed; for example, the shaping optics may be a convergent lens focused behind the light areas, with respect to the direction of emission of light rays from the source;

 the optical shaping is such that the areas illuminated by each light zone of the same group overlap and are essentially superimposed; thus each group forms a pixel that can take different colors; the image of the light source after projection by the shaping optics then corresponds to the image formed by the positioning of the different groups supplied with electricity;

the arrangement of the light zones is identical in each of the light groups; a pixellization of the light source is thus obtained, capable of producing a light beam with distinct parts of different colors that can be adapted, in particular according to a choice of configuration by the user or by a computer, or by a system image processing according to the road environment;

 the light groups are arranged in the light source in rows and columns; this allows a simpler control of the light areas to form a pattern;

the rows and the columns comprise a number of light groups sufficient for at least one pattern of part or all of a lighting beam of the route can be made on the light source; this makes it possible to have a luminous pattern which once sent on the road, in particular by means of reflection and / or projection, will give a part or all of a light beam with a photometric distribution required for this beam, forming thus part or all of a lighting beam;

 each of the light groups comprises only a first, a second and a third light zone, emitting, when electrically powered, light rays of respectively red, blue and green color; light groups forming RGB sources are thus obtained, which makes it easier to adjust the color emitted at a light group; for example, this makes it possible to obtain different colors of white, namely whites with different shades;

 the rods of the first, second and third light zones have chemical compositions different from each other, so that these rods emit light rays of color respectively red, blue and green when they are electrically powered; it is a means of realization of the RGB colors;

each light zone comprises a layer of a luminophore arranged above the rods so that the phosphor receives the rays emitted by the rods and in turn emits light rays, corresponding to the light rays emitted by the corresponding luminous zone, the phosphor layers of the light zones of each light group being of different chemical compositions, so that each light zone of the same light group has a different color; the phosphor layers of the different light areas have chemical compositions different from each other, so that:

 a first light zone whose phosphor layer has a first chemical composition emits light rays of a white color with a hint of yellow,

 a second light zone, the phosphor layer of which has a second chemical composition, emits light rays of a white color with a shade of green,

 o a third light zone whose phosphor layer has a third chemical composition emits light rays of a white color with a shade of blue;

this allows for example a lighting beam with shades promoting perception;

 each light zone comprises a layer of a luminophore arranged above the rods so that the phosphor receives the rays emitted by the rods and in turn emits light rays, corresponding to the light rays emitted by the corresponding luminous zone, in which the phosphor layer on the rods of each light zone of the same light group, or even of the entire light source, forms a single phosphor layer, in particular of constant thickness, and in which the rods of the different zones luminaires have chemical compositions different from each other, so that each luminous group comprises:

a first light zone whose rods have a chemical composition enabling them to emit light rays of violet color, so as to this luminophore emits light rays of a white color with a shade of yellow, o a second zone in luminous whose rods have a chemical composition allowing them to emit light rays of blue-green color, so as to what this luminophore emits light rays of a white color with a shade of green,

 o a first zone in light whose rods have a chemical composition enabling them to emit light rays of blue color, so that this phosphor emits rays of light of a white color with a shade of blue;

this allows a simpler realization of the recovery of rods by a luminescent material, in particular by deposition; each light zone comprises a layer of a luminophore arranged above the rods so that the phosphor receives the rays emitted by the rods and in turn emits light rays, corresponding to the light rays emitted by the corresponding luminous zone, in which the phosphor layer on the rods of each light zone of the same luminous group, or even of the entire light source, forms a single phosphor layer, each luminous group comprising:

 a first light zone whose phosphor layer has a first thickness such that this phosphor emits light rays of a white color with a hint of yellow,

a second light zone whose phosphor layer has a second thickness such that this phosphor emits light rays of a white color with a shade of green, a third light zone whose phosphor layer has a third thickness such that this phosphor emits light rays of a white color with a shade of blue,

the first phosphor thickness having a value greater than that of the third phosphor thickness, the second phosphor thickness having a value between that of the first thickness and that of the third thickness; this allows a simpler embodiment of the light source, which can thus have rods of the same chemical composition, for example rods emitting light rays of blue color; the production of the phosphor layer can be easily performed by molding or by successive deposits with caches;

the phosphor layers have the following thicknesses:

 the phosphor layer of the first zone has a thickness of approximately 390 μm,

 the phosphor layer of the second zone has a thickness of approximately 325 μm,

 the phosphor layer of the first zone has a thickness of about 260 μm;

 the light device is a road lighting device, including a projector;

the light device is a road lighting device and comprises an optical element or a set of optical elements, in particular one or more reflectors and / or one or more lenses, arranged to project the image of the source light, so as to form said light beam, said light beam being a beam of illumination of the road, such as a dipped beam, a motorway light, a fog lamp or a road light; the present invention facilitates the realization of a lighting beam with different white colors; the resolution of the element optical or set of optical elements is such that one can not visually separate in the beam the contributions of different light areas of a same group; in this case, each group appears after projection as a pixel of an image of the source, whatever the light zone of this activated group; only the color of this pixel changes according to the activated light zone; the image of the source therefore corresponds to the image of the pattern formed by the set of groups;

the light beam comprises distinct parts of different colors corresponding to lateral parts of the illumination beam, at least one part intended to illuminate below the cutoff height and, optionally, at least one part intended to illuminate above the cutoff height; this makes it possible to have different colors according to the parts of the road and in particular, on the aisles, on the road and above the road; this allows the driver to better distinguish these different parts. The invention also relates to a road lighting system comprising:

 a light device according to the invention,

 means for controlling the light source,

 an image sensor of the road in front of the vehicle,

a calculator able to identify inside this image several portions corresponding to categories of sectors of the road and its environment, and to send a signal corresponding to said control means so that said light zones are powered by in a different way according to the light groups, so that several sectors of the road and its environment belonging to a different category are illuminated, at least a plurality of said illuminated areas being illuminated with a different color;

we have a beam adaptable to the road and its environment.

 The lighting system according to the invention may comprise the image sensor and / or the computer and / or the control means.

 The invention also for o jet a vehicle comprising a light device or a lighting system according to the invention, in particular connected to the power supply of the vehicle.

 The invention also relates to a control method of a light device according to the invention.

 The control method according to the invention may optionally include one or more of the following characteristics:

 this method comprises a step of sending a control signal depending on the environment of the road and the road on which a vehicle comprising the light device is traveling, and a step of selecting the light areas to be electrically powered according to this control signal; this makes it possible to automate the adaptation of the light beam to the road on which the vehicle is traveling;

- The control signal is sent by a sensor and / or a computer that includes the projector and / or the vehicle;

 the light beam comprises distinct parts and the light areas are selected so that the different colors of the distinct parts of the light beam are chosen from:

o a white color with a shade of green, when the vehicle is traveling in the countryside, o a neutral white color or with a shade of blue, when the vehicle is driving on the highway, o a white color with a hint of yellow when the vehicle is traveling in the city;

surprisingly, the applicant has found that some colors favor the visibility according to the part they illuminated, especially certain white colors with a given shade; this embodiment option corresponds to shades of white allowing better visibility in these traffic conditions;

 the light beam has at a given moment a single color and the light areas are selected so that the light beam takes one of the following colors:

 o a white color with a shade of green, when the vehicle is traveling in the countryside,

 o a neutral white color or with a shade of blue, when the vehicle is driving on the highway, o a white color with a hint of yellow when the vehicle is traveling in the city;

 the method comprises the following steps:

 o capture an image of the road in front of the vehicle, o identify inside this image several portions corresponding to categories of sectors of the road and its environment,

o selecting the light areas to be powered electrically so that the light areas are fed in a different way according to the light groups, so that several sectors of the road and its environment belonging to a different category are illuminated, at least several of said sectors illuminated being illuminated with a different color;

this method makes it possible to adapt the distribution of the different parts of different colors in the light beam, so that they are superimposed on the different categories of sectors. It thus makes it possible to optimize the visibility according to the evolution of the road and its environment, in particular as real;

 at least the different colors associated with the different categories, correspond to white colors of different shades;

 the light areas are powered so that the lighting beam:

 o has at least a portion of a white color with a shade of green lighting the sides of the road,

 o has at least a portion of a neutral white color or a shade of blue illuminating the road surface,

 o has at least a portion of a white color with a hint of yellow above the road and / or aisles;

surprisingly, the applicant has found that these colors particularly enhance the visibility on these categories of road sector and its environment.

The light device, the lighting system and / or the control method according to the invention may optionally comprise one or more of the following characteristics: the different colors, including the different white colors, have non-intersecting MacAdam ellipses;

white colors are defined according to CIE 1931 standards; the different colors are inside the zone defined by the limit lines in the coordinate diagram (x, y) of the following CIE 1931 standards:

 o the so-called green limit (W12) of equation: y = 0.150 + 0.640 x

 o the yellowish green boundary (W23) of equation: y = 0.440 o the so-called yellow limit (W34) of equation: x = 0.500 o the so-called red violet limit (W45) of equation: y = 0.382

 o the so-called violet limit (W56) of equation: y = 0.050 +

0.750 x

 o the so-called blue limit (W12) of equation: x = 0.310; these different colors correspond to white colors of different shades.

 The shades of the whites mentioned above are therefore more or less close to certain limit lines, depending on the chosen shade. For example: the white with a shade of yellow is closer to the so-called yellow limit, the white with a shade of blue is closer to the so-called blue limit, the white with a shade of green is closer to the so-called green limit .

 Other features and advantages of the invention will appear on reading the detailed description of the following nonlimiting examples, for the understanding of which reference will be made to the appended drawings, in which: FIG. 1 represents a perspective view of transmission means, such as those included or used in the various objects of the invention;

 Figure 2 shows a schematic sectional view of Figure 1 along the axis AA;

FIG. 3 shows the projection on a vertical screen, notably at 25 meters, of a road beam emitted by a vehicle light device according to the invention and comprising the emission means of FIG. 1; FIG. 4 shows the projection on a vertical screen, particularly at 25 meters, of a passing beam emitted by a vehicle light device according to the invention and comprising the transmission means of FIG. 1;

FIG. 5 represents a group of transmission means comprising the transmission means of FIG. 1;

 Figure 6 shows a color chart defining an area encompassing the different shades of white;

- Figure 7 shows an environment of the road seen from the driver's seat of the vehicle, with schematic landmarks;

 FIG. 8 represents the projection on a vertical screen, notably at 25 meters, of a road beam emitted by a vehicle light device adapted to the environment of the road of FIG. 7;

 FIG. 9 represents transmission means according to another embodiment;

 FIG. 10 represents a light device according to the invention.

FIG. 10 illustrates an exemplary light device D of a vehicle according to the invention. This light device D is a projector capable of emitting a white light beam.

 The light device D comprises a box B closed by a transparent glass G, thus delimiting an interior volume.

Inside this volume, there is arranged a light source S which, in this example, comprises all of the transmission means capable of generating the light rays r1, r2, making it possible to form a beam of white color. The light device D comprises at least one connection means C connected to the light source S and intended to be connected to a power supply A for supplying power to the emitting means of the light source S.

 In this example, the transmission means and the connection means C are arranged so as to confer on the light beam different colors, in particular different white colors, according to the power supply received by the connection means.

 In this example, the interior volume comprises a shaping optics 0 arranged to project the image of the transmitting means, so as to form the light beam. In this example, this optic 0 is a convergent lens focused on or slightly behind the light source S.

 FIG. 1 illustrates a light source S comprising three light zones 1, 2, 3. In this example, these three light zones 1 to 3 are the transmission means.

 Figure 2 is a section along AA of the light source S.

 In this example, the light source S is a rod light source.

 The light source S comprises a substrate 10 from which, in a preferred direction, sticks 11, 12, 13 distributed in a first light zone 1, a second light zone 2 and a third light zone 3 respectively extend.

 This substrate 10 is, especially in this example, silicon, which represents a much lower cost than conventional LEDs, in which the substrates are sapphire. The rods 11, 12, 13 may be obtained by crystalline growth on this substrate 10.

The rods 11, 12, 13 are arranged to form rods of a semiconductor material EL. The rods 11, 12, 13 may for example be formed essentially of gallium nitride.

 For example, these rods 11, 12, 13 comprise a core of semiconductor material capable of being doped with electrons, around which is formed a first layer of semiconductor material capable of having electron deficits, in which case sometimes speaks of doped layer in "holes" or positive charges. At the interface of this soul and this first layer, an intermediate layer is formed where the electrons and the electron deficits are recombined. Thus, each rod 11, 12, 13 is an electroluminescent semiconductor element.

 A nucleation layer 19 is formed on the substrate 10 and around the rods 11, 12, 13.

 The rods 11, 12, 13 are here at a distance of about 30 μm and each have a height, taken from the nucleation layer 19 to their apex, of 2.5 μm. Their thickness, which corresponds here to the width of the rods in FIG. 1, is 1.5 μm. Note that Figures 1 and 2 are schematic; the scales should not be taken into consideration between the different elements.

 The light source S therefore essentially comprises a substrate 10 forming a plate bristling with a multitude of small rods 11, 12, 13 electroluminescent and submillimetric, namely whose largest dimension is less than one millimeter.

 Between each rods 11, 12, 13 of the same zone 1, 2, 3 is deposited an electrically conductive layer, electrically joining these rods, thus forming a separate anode 25, 26, for each of the three light zones 1, 2, 3 .

The three anodes 25, 26 thus formed are in contact with the nucleation layer 19, which itself is in contact with the cathode formed by the substrate 10. Thus, by connecting the anodes 25, 26 and the cathode 10 to a power source, each of the different light zones 1, 2, 3 can be independently supplied with electricity.

 According to an embodiment of the invention, each anode is connected via electrical conductors 31, 32, 33, to one or more positive terminals of an activation means 20, intended to be connected to the positive terminal of the source of power. power supply of the vehicle. Similarly, the cathode 10 is connected via an electrical conductor 34 to the negative terminal of the activation means 20. The activation means therefore allows the power supply of each of these light areas 1, 2, 3.

 The light source S is therefore suitable for each of its light zones 1, 2, 3 to be selectively supplied with electricity, in particular by the activation means 20. It is therefore possible to control this light source S by selective activation of its areas.

 The control can be achieved by a specific means separate from the light device, or, as in this example, by a control device integrated in the light device D.

 In this example, the control is carried out directly by the activation means, which thus forms a control device 20. The latter is connected on the one hand to each anode 25, 26, via the electrical conductors 31, 32, 33, 34 and on the other hand to a connector C, intended to be connected to the electrical power supply K of the vehicle via an electric harness 35.

The connector C, the control device 20 and the light source S are for example mounted on the same printed circuit board (not shown). The electrical conductors 31, 32, 33, 34 are formed by electronic tracks of this card. Likewise, other electronic tracks connect the control device 20 to the connector C. The light areas 1, 2, 3 can be made brighter by depositing a reflecting layer 17, 18 on the nucleation layer 19. This reflecting layer 17, 18 is for example deposited on the nucleation layer 19 before growth of the rods , then holes are formed in this reflective layer 17, 18, as well as in the nucleation layer, before growth of the rods 11, 12, 13 on the substrate 10. This reflecting layer 17, 18 may be aluminum. It also has the advantage of allowing a better current distribution.

 To have a higher brightness, especially in the context of the luminous device D, the rods of the light areas can have the following characteristics:

 a thickness of between 1.4 and 1.6 μm, for example 1.5 μm,

 a height of between 2 and 3 μm, for example 2.5 μm,

a distance between each rod of between 20 and 30 μm, for example 30 μm.

 According to one embodiment of the invention, it is based on a rod light source by arranging it to have selectively activatable zones.

 The light device D makes it possible to generate a light beam, such as for example a road beam.

 The rods 11 of the first light zone 1 are arranged to emit a white color with a shade of green.

 The rods 12 of the second light zone 2 are arranged to emit a white color with a shade of yellow.

 The rods 13 of the third light zone 3 are arranged to emit a white color with a shade of blue.

In general, in the present application, and in particular in the examples illustrated, the white colors, of the light device, the lighting system and / or the control method according to the invention can be defined according to CIE 1931 standards.

 For example, the different white colors, in particular those mentioned above, may be within the zone defined by the following limit lines in the coordinate diagram (x, y) of the CIE 1931 standards, illustrated in FIG. 6:

 the so-called green limit (W12) of equation:

 y = 0.150 + 0.640x

 the yellowish green boundary (W23) of equation: y = 0.440 the so-called yellow boundary (W34) of equation: x = 0.500

 the so-called violet red limit (W45) of equation: y = 0.382 the so-called violet limit (W56) of equation:

 y = 0.050 + 0.750x

 the so-called blue limit (W61) of equation: x = 0.310.

 These different colors correspond to white colors of different shades of white.

 In particular, in this application, the different colors, for example the different white colors, have non-intersecting MacAdam ellipses.

 The shades of the whites mentioned above are therefore more or less close to certain limit lines depending on the chosen shade. For example: the white with a shade of yellow is closer to the so-called yellow limit, the white with a shade of blue is closer to the so-called blue limit, the white with a shade of green is closer to the so-called green limit .

According to one embodiment of the invention the light zones 1 to 3 are arranged with the shaping optics 0 so that the rays emitted by the light zone or zones emitting light rays of identical white color all form together, after deviation by the shaping optics 0, a complete illumination light beam. For example, the driver or control device 20 may send a control signal to activate the light areas to generate the corresponding colors.

 The present application is not limited to a road beam, which is a long-worn beam. It can be applied to other lighting beams of the road such as a low beam, a motorway light, a fog light or a fire.

 According to another embodiment of the invention, the light areas 1 to 3 are arranged with the shaping optics 0 so that several light zones capable of emitting light rays r 1, r 2 of different white colors together form a beam of light. road lighting.

 FIG. 3 illustrates an example of a road beam Fl generated by the light zones 1 to 3. FIG. 3 represents the projection on a vertical screen, notably at 25 meters, of the road beam F1, with also the representation of the horizon H and a vertical axis V, intended to be centered generally in front of the vehicle.

 This lighting beam comprises two lateral parts, referenced 61 for one and 61 'and 61 "for the other, having a white color with a shade of green, a lower part 63 intended to illuminate below the cutoff height. h and having a neutral white color or with a shade of blue, and an upper portion 62 for illuminating above the cutoff height h and having a white color with a shade of yellow.

Thus, the side portions 61, 61 'and 61''of the road beam Fl are particularly suitable for illuminating vegetation areas on the side of the road. The lower part 63 of the beam is particularly adapted to illuminate a bitumen area of the road. The upper portion 62 is particularly suitable for illuminating an area located above the bitumen and / or road signs. Indeed, the plaintiff surprisingly, these colors particularly enhanced the visibility of these road sectors and their environment.

 The lateral parts 61, 61 'and 61' ', the upper part 62 and the lower part 63 are respectively formed by the rays initially emitted by the rods 11, 12 and 13 of the first light zone 1, the second light zone 2 and the third light zone 3.

 Thus, when the driver or a computer sends an activation signal of the road beam Fl, the control device activates the light areas 1 to 3.

 According to another embodiment of the invention, the rod light source and the shaping optics are arranged so as to form a passing beam, as illustrated in FIG. 4.

 This passing beam F2 similarly comprises the beam F1 of FIG. 3, a lower portion 63 and lateral portions 61 and 61 '.

 The lateral portion 61 'on the left is delimited in the upper part by a cutoff line 64 located at the cutoff height h. Similarly, the lower portion 63 is delimited in height by a horizontal cutoff line 65 located at the cutoff height h. On the other hand, the right lateral part 61 has an oblique cut 66, which rises to the right in order to be able to illuminate on the aisles.

 In this example, the lower part 63 and the right lateral part 61 of the passing beam F2 are respectively identical in shape and in color to the lower part 63 and the right lateral part 61 of the road beam F1 of FIG.

According to another embodiment, the light source comprises at least five light zones so as to form a road beam such as that Fl in FIG. 3 and also a passing beam such as that F2 in FIG. For that, the The distribution, not shown, of the five light zones is arranged to form the different parts of the emitted light beam, so as to achieve a road beam configuration Fl and a passing beam configuration F2.

 For example, at least three light areas are able to form and emit white rays with a shade of green, to form the side portions 61, 61 ', 61' '. The upper 62 and lower 63 parts of the road beam are each formed by a bright areas as in the previous embodiment.

 Thus, when the driver activates the road beam, all the light zones are activated and all the corresponding portions of the light beam, 61, 61 ', 61' ', 62, 63, are formed so that the beam is obtained. Fl.

 On the other hand, when the driver activates the passing beam, in order not to dazzle the passengers arriving in front of him, a control signal is sent to the control device 20, which then deactivates the light zone (s) allowing the formation of the part. high 62 of the beam, and the light zone for the formation of the left side part 61 '' above the cutoff height h. Therefore, only the right lateral part 61, the lower part 63 and the left lateral part 61 below the cut-off height h are lit, thus forming the passing beam F2.

 One can thus have a projector D which with a single source forms both the passing beam and the road beam, while providing its two beams of the arrangement in separate parts, these parts having different shades of white.

It is still possible to further improve the fit of the different parts of distinct colors inside of the light beam. Such an improvement is described hereinafter with reference to FIGS. 5, 7 and 8.

 As can be seen in FIG. 5, the light source can comprise several groups G11, G12, G21, G22. The light areas are distributed among these groups.

 In this example, each of these groups has an identical distribution of rods and light areas. For the sake of clarity only the first group G11 has been shown. The structure of this first group corresponds to that of the light zones of FIG. 1. Thus each group G11, G12, G21 and G22 comprises three light zones 1, 2 to 3, able to emit respectively green, yellow and blue color rays. .

 Moreover, in this example, the source S has as many anodes as there are groups G11, G12, G21, G22 and only light zones 1, 2, 3. Each light zone is thus connected to the control device 20 by tracks. 31, 32, 33, 42, 52, 62. For the sake of clarity, only one connection track 42, 52, 62 has been shown for each group G12, G21 and G22, although there are three these groupings.

 The light source may comprise only a connection track 34 connected directly to the cathode, which is formed by the substrate 10.

 The light source S may comprise a plurality of these groups arranged in rows and in columns. Each group thus forms a pixel, whose control device 20 is able to choose the white color according to the activated light zone.

The light device can be connected for example to a camera (not shown) which records an image of the road environment. By way of example, FIG. 7 illustrates an image R of this road environment. The dots represent the volume illuminated by the lighting beam of the road.

 This image shows several sectors of the road environment: the aisles on either side of it, with a road sign on the right, as well as an area above the road between aisles.

 The camera is connected to a computer (not shown), which processes these images, in the example of Figure 7, the image R. The computer defines different sectors in the image.

 For example, by recognizing in a known manner the demarcations on the ground, it defines the sector corresponding to the bitumen. It can also thanks to the lines of the relief near to define the aisles and the zone located above. It can also define areas corresponding to road signs.

 Then, the computer identifies the groups G11, G12, G21, G22, corresponding to these sectors, for example so that the sector division of the image R corresponds to a division into sectors of the light source.

 The calculator also identifies which color is to be assigned to each of these groupings according to the sector of the light source to which they are attached.

 Then, the computer sends to the control device, the instructions for defining which light zone 1 to 3 of each group G11, G12, G21 and G22 must be activated so that each group emits the color corresponding to the sector with which it is associated.

 The optical shaping project then the image of the light source on the road, in particular in the same direction as the shooting of the camera.

For example, the image R is projected so that if a vertical screen was placed in front of the vehicle, as shown in FIG. 8, the distribution of the beam portions F3 on this screen would correspond to the sectorization performed on the image R received by the computer. As a result, the parts of the beam will correspond to the road environment.

 Thus, in FIG. 8, it is possible to observe a projection of the beam on a screen 25 meters from the beam F3 generated according to this embodiment. In this beam F3:

 side portions 161 and 161 'project on the relief of the aisles; these side portions 161 and 161 'are white with a green hue; they are generated by the activation of the first light zones 1 of the groups selected by the control device 20 as corresponding to the sectors associated with the aisles;

 a lower part 163 projects on the bitumen; this low lateral part 163 is white with a blue hue and is generated by the activation of the third light zones 3 of the groups selected by the control device 20 as corresponding to the sector associated with the bitumen;

 an upper part 162, which is white with a yellow hue, projects above the aisles and the bitumen; this upper part 162 is white with a yellow hue and is generated by the activation of the second light zones 2 of the groups selected by the control device 20 as corresponding to the sector above the aisles and the bitumen;

an additional part 167, which is also white with a yellow hue, projects onto a traffic sign; it is generated by the activation of the second light zones 2 of the groups selected by the control device as corresponding to the sector defined by the panel.

It then becomes possible to enhance the visibility of certain sectors of the road or the environment of the road, by adapting the hue of a portion of the light beam to area of the road or part of the illuminated environment.

 In the preceding examples the rods emit rays whose color corresponds to that emitted in the beam at the output of the light device. However, other solutions are possible, such as those mentioned in this application before the description of the figures.

 For example, as illustrated in FIG. 9, a first light zone 201 and a second light zone 202 each emit a different color, while the rods, respectively 211 and 212, of these zones emit the same color, for example a blue color.

 For this, the rods 211, 212, of the entire light source are covered with a phosphor layer 241, 242. This phosphor after absorption of blue light rays reemets white rays.

 The phosphor layer has a different thickness depending on the light areas, thus allowing the light areas above which the phosphor thickness is identical to emit a white color with the same given hue.

 For example, below a certain thickness, the phosphor will be saturated by the emitted rays, and all will not be converted. The white light emitted will then have a blue hue. Above a certain thickness, almost all emitted rays will be converted. The white light emitted will then have a yellow tint. With an intermediate thickness, the white light emitted will have a green hue.

In the example illustrated in FIG. 9, the phosphor layer above the rods 211 of the first light zone 201 has a thickness 241 such that the outgoing light rays emitted by the first light zone 201 are of a white color with a green tint. . Thus when the control device 220 activates the first light zone 201 by feeding, via the anode 225 and the electronic track 231, this first light zone 201 emits a white color with a green tint.

 Similarly, when the control device 220 activates the light zone 202 by means of the anode 226, via the electronic track 232, the second light zone 202 emits a white light with a yellow tint. Note that as in the previous embodiments, the cathode is formed by the substrate 210 common to all the light areas. This cathode is connected via an electronic track 234 to the control device 200. The thickness 242 of the phosphor above the rods 212 of the second light zone 202 is greater than that 241 above the rods 211 of the first light zone 201 This difference in thickness d is such that the phosphor above the rods will emit rays of light of white color with a yellow hue.

 A third light zone, not shown, comprises a phosphor thickness lower than that above the first light zone, so that it will emit a white color with a blue hue.

 These light areas 201, 202 can be arranged and controlled by the control device 220 in the same way that the light areas 1 to 3 are controlled by the control device 20 in the previous embodiments, in order to confer on the light beam Fl , F2, F3, and to its different parts the desired colors or required.

Although the illustrated examples apply to a headlamp and to road lighting beams, the present application can be applied to a traffic light. For example, according to certain directions with respect to the traffic light, the signaling beam may have different colors. This makes it possible to confer a vehicle signature with respect to an outside observer. Similarly, it can be applied to light devices vehicles emitting a uniform color, but can be changed according to a command of the user or a computer.

Claims

A vehicle light device (D) comprising:

 a semiconductor light source (S) comprising a plurality of submillimeter-sized electroluminescent rods, all of said rods being divided into several distinct light zones (1 to 3; 201, 202), at least one light zone being arranged to emit light rays of a different color from the light rays emitted by at least one other light zone,

 at least one shaping optics (0) adapted to receive the light rays (r1, r2) emitted by the light zones and to deflect them out of the light device, said light source and said shaping optics being arranged in order to form a light beam and to be able to give this light beam several different colors.

 2. Lighting device according to any one of the preceding claims, wherein said light source (S) is arranged so that said light areas (1 to 3; 201, 202) are able to be supplied with electricity independently of one another. others and said rods (11 to 13; 211, 212) of the same light zone are electrically powered when the light zone is electrically powered.

Light device according to any of the preceding claims, wherein the chemical composition of the rods of at least one light zone differs from the chemical composition of the rods of at least one other light zone, so that the rods of the at least one light zone emit light rays of a color different from that of the light rays emitted by the rods of the at least one other light area.

 4. The light device as claimed in any one of the preceding claims, wherein each light zone (201, 202) comprises a layer of a phosphor arranged above the rods (211, 212) so that the phosphor receives the rays emitted by the rods and in turn emits light rays, corresponding to the light rays emitted by the corresponding light zone, at least two light zones differing from each other by:

- the chemical composition of their sticks,

 the chemical composition of their phosphor layer, and / or

the thickness (241, 242) of their phosphor layer.

 Light device according to one of the preceding claims, in which the light areas

(1 to 3) are distributed in a light group (G11, G12, G21, G22), each of these groups comprising at least two light zones, and for each of the light groups, each light zone being able to emit light rays a color. different from that of the light rays that other light areas of this light group are able to emit.

 6. Light device according to claim 5, wherein the shaping optics (0) is such that the areas illuminated by each light zone (1 to 3) of the same group overlap and are substantially superimposed.

 7. Lighting device according to claim 6 or 7, wherein the arrangement of the light areas (1 to 3) is identical in each of the light groups (Gll, G12, G21, G22).

The luminous device according to claim 7, wherein the light groups (G11, G12, G21, G22) are arranged in the light source in rows and columns, the rows and the columns comprise a number of light groups sufficient for at least one pattern of part or all of a light beam (F1, F2, F3) of the road can be achieved on the light source (S).

 9. Light device according to any one of claims 5 to 8, wherein each of the light groups comprises only a first, a second and a third light areas, emitting when they are electrically powered light rays of color respectively red, blue and green.

 The light device according to any one of the preceding claims, wherein said light device is a road lighting device (D).

 Light device according to any one of claims 5 to 9, wherein said light device is a road lighting device (D) and comprises an optical element or a set of optical elements, arranged for projecting the image of the light source so as to form said light beam, said light beam being a light beam of the road (F1, F2, F3).

 The luminous device according to claim 11, wherein the light beam comprises distinct portions of different colors corresponding to side portions (61, 61 ', 61' ') of the illumination beam, to at least a portion (63). for illuminating below the cutoff height (h) and, optionally, at least a portion (62) for illuminating above the cutoff height (h).

 13. Road lighting system comprising:

 - A light device according to one of claims 10 to 12,

 a control means (20) for the light source,

 an image sensor of the road in front of the vehicle,

a calculator able to identify inside this image (R) several portions corresponding to categories of sectors of the road and its environment, and to send a signal corresponding to said driving means so that said light areas are fed in a different way according to the light groups, so that several sectors of the road and its environment of a different category are illuminated, at least a plurality of said illuminated areas being illuminated with a different color.

 14. A method of controlling a light device according to one of claims 1 to 12 or a lighting system according to claim 13, this method comprising a step of sending a control signal according to the environment. of the road and the road on which a vehicle comprising the light device is traveling, and a step of selecting the light areas (1 to 3; 201, 202) to be powered electrically as a function of this control signal.

 The light device, system, or method according to one of the preceding claims, wherein the different colors, including the different white colors, have non-intersecting MacAdam ellipses.