WO2018007385A1

WO2018007385A1 - Light device with a light source having a lighting area and a communication area

Info

Publication number: WO2018007385A1
Application number: PCT/EP2017/066638
Authority: WO
Inventors: Gilles LE-CALVEZ
Original assignee: Valeo Vision
Priority date: 2016-07-05
Filing date: 2017-07-04
Publication date: 2018-01-11
Also published as: FR3053759B1; FR3053759A1

Abstract

The present invention relates to a light device of a vehicle comprising a light source (S) with sub-millimetre electroluminescent rods (11, 12) distributed in a first emission area (1) and in a second emission area (2), each of said areas being capable of being activated independently, the first emission area being arranged so as to be capable of emitting light rays (r1, r2) involved in the formation of a light beam (F), and said second emission area being arranged so as to be capable of emitting a communication signal.

Description

LUMINOUS DEVICE WITH A LIGHT SOURCE HAVING A LIGHTING ZONE AND A COMMUNICATING ZONE

The present invention relates to a vehicle light device comprising a transmitter of a communication signal.

It is known light devices comprising components specifically dedicated to the transmission of a communication signal in addition to light sources intended to allow the emission of a light beam. The use of such a device generates an additional cost.

It has also been developed light devices including light emitting diodes, LED or LED, in which the supply of these LEDs is by modulating the voltage of their power supply, so as to transmit a signal carried by the light beam of signaling or lighting the road. With the same light source, it is thus possible both to generate a photometric function and to communicate. These devices, however, have a risk of fluctuation of the light beam, which can cause discomfort for the driver of the vehicle with this light device, or for those of the following vehicles, tracked, or coming in the opposite direction.

The technical problem that the invention aims to solve is therefore to improve the perception of a luminous flux of a vehicle light device capable of transmitting a communication signal.

For this purpose, a first object of the invention is a vehicle light device comprising a light source comprising electroluminescent rods of submillimeter dimensions, said rod light source, the rods being distributed in a first transmission zone and in a second emission zone, each of these emission zones being independently activatable, the first emission zone being arranged to be able to emit light beams participating in the formation of a beam light, and the second transmission zone being arranged to be able to emit a communication signal.

Thus, by taking advantage of a rod light source with selectively activatable zones, it is possible with the same light source to emit both the light rays intended to produce the light beam and the communication signal separately. . As a result, the transmission of the communication signal is not liable to generate a fluctuation of the light beam emitted by the light device, in particular of a road lighting beam or of a signaling beam.

In addition, according to certain embodiments of the invention, this makes it possible to arrange the second emission zone so that the latter emits a wavelength specific to the photoreceptors. This makes it possible to improve, particularly with respect to visible light communication systems, or VLC (for "Visible Light Communication" in English), the scope of the transmission of the communication signal, in particular within the framework of a vehicle-to-vehicle communication. A photoreceptor is a light transducer that provides an electrical signal in response to incident optical radiation on its surface. Photoreceptors are devices that convert optical energy into electrical energy.

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

the light beam fulfills a given photometric function, in particular a regulatory photometric function; it is thus possible to directly integrate the second emission zone in a light source of a light device performing this photometric function;

the photometric function is a signaling function or a lighting function of the road; this makes it possible to communicate with the outside of the vehicle, in particular with other vehicles; the signaling function is chosen from a daytime running light (also called DRL for "Day Running Light"), a rear position light, a stop light, a rear fog light, a direction indicator, a reversing light;

the lighting function of the road is chosen from: a passing beam, a road beam (also called a "long beam" or "full beam" in English), a motorway beam, a front fog beam; the motorway beam, also called the "motorway" beam, is a horizontal cut-off beam intermediate between that of a passing beam and a road beam, intended to be used on the motorway when vehicles are followed from sufficiently far away;

the photometric function is a lighting function of the interior of the vehicle; this makes it possible to communicate with the interior of the vehicle, in particular with other onboard devices of this vehicle, notably embedded in the passenger compartment;

the light device comprises optical elements arranged to deflect the light rays emitted by the first transmission zone and the signal emitted by the second emission zone from the light device, so as to form the light beam and to send the light signal. communication within this light beam; common optical elements are thus used, and therefore fewer in number than with specific optical elements;

the first emission zone and the second emission zone are arranged to emit light rays of identical wavelengths; this makes it possible to produce a simple light source, whose emission zones differ by their connection, and when they are implemented by their control; moreover, in the case of a signaling device, this makes it possible to keep an illuminating surface corresponding to all of the emission zones;

the second emission zone has an area less than one tenth of the sum of the areas of all the emission zones of said light source; thus, the fluctuations on the luminous flux emitted by the second emission zone will be less perceptible; this is particularly useful in the case of use of the light device to emit messages contained in the communication signal and containing a constant value, thus more likely to bring about a variation of the average power of the transmitted signal and therefore of the light radiated;

the second emission zone has an area less than 1 millimeter squared (mm ² ); such a size is sufficient for the fluctuations on the second emission zone to be imperceptible; it is therefore also a particularly useful embodiment in the case of use of the light device for transmitting messages contained in the communication signal and containing a constant value;

the first emission zone and the second emission zone are arranged in such a way as to emit light rays and electromagnetic radiation of different wavelengths;

the second emission zone is arranged to emit infrared rays; thus, the signal and its possible fluctuations are not perceptible; in addition, the second transmission zone can be used to transmit a signal while the first transmission zone is not activated, for example by day;

the rods of the second emission zone emit blue light rays when they are electrically powered, and wherein said light source comprises a phosphor layer arranged on the rods so as to receive the blue light rays, this a phosphor layer having a composition such that it converts these light rays into infrared rays; it is a way of producing an infrared emission zone with a rod light source;

the rods of the first emission zone emit light rays of blue color when they are powered electrically, and wherein the light source comprises a phosphor layer arranged on the rods to receive light rays of blue color, said phosphor layer having a composition such as to convert these light rays into light rays of a White color ; for example, this makes it possible to integrate the communication signal with a reversing light or with a lighting beam of the road;

the rods of the first emission zone and the rods of the second emission zone are identical; for example, the rods can all emit light rays of blue color, the differentiation of the emission wavelength of each zone being achieved by the nature of the phosphor above these emission zones;

the second emission zone has an area less than one third of the sum of the areas of all the emission zones of the light source;

the light device comprises a plurality of second transmission zones separated from each other by portions of the first transmission zone and / or by different first transmission zones; this allows a better cooling of the first emission zone and in general of the light source; in fact, since the second zone does not usually work all the time, the portion of the substrate of the light source under this second emission zone will also be used for cooling, even in the absence of signal transmission;

the sum of the areas of the second emission areas is less than one third of the sum of the areas of all the emission areas;

each transmission zone is divided into subgroups in which the rods of the corresponding transmission zone are distributed, each subgroup being selectively activatable; the selectively activatable subgroups have a size less than or equal to 350 micrometers, in particular less than or equal to 100 micrometers; the rod light source is advantageous for such an embodiment, which makes it possible to have a less bulky light module;

the light device comprises a control device arranged to selectively activate the first transmission zone and the second transmission zone, and possibly to independently modulate the power supply of the second transmission zone so that it emits a communication signal; the control of the emission zones is thus controlled directly from the light device; this allows easier control of these transmission areas and does not unnecessarily occupy the vehicle communication network, including the vehicle communication network controlled by a multiplexed network management device, in particular called CAN (for " Controller Area Network ";

the light device is selected from a projector, a vehicle rear light, a fog light, a license plate lighting device, a direction indicator; this allows for example the light device to exchange information with a vehicle followed or following, or with terminals on the road;

the light device is a lighting device of the vehicle interior; this allows for example the light device to communicate with an onboard computer; for example, the luminous device is chosen from: a ceiling lamp, a side wall, a reading lamp;

the light device is a device for illuminating the license plates of the vehicle.

Another object of the invention is a vehicle comprising a light device according to the invention.

Another object of the invention is a method for controlling a light source of a vehicle light device, said source light source comprising electroluminescent rods of submillimetric dimensions, said method comprising the following steps:

a step of activating certain rods distributed in a first emitting zone of the light source so as to emit light rays forming, directly or after deviation, a light beam fulfilling a given photometric function,

a step of activating certain rods distributed in a second emission zone of the light source so as to emit a communication signal.

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

the step of activating certain rods distributed in the second emission zone is carried out by modulating the power supply of the rods of the second emission zone;

the second emission zone has an area less than one tenth of the sum of the areas of all the emission zones of said light source;

the second emission zone has an area less than 1 mm ² ;

the second emission zone has an area less than one-tenth of the sum of the areas of all the emission zones of the light source and the modulation of the power supply of the rods of the second emission zone is made in such a way as to the communication signal contains messages of constant value;

the method is implemented so as to drive a light device according to the invention or the light device of a vehicle according to the invention. Furthermore, in the light device, the vehicle and the control method according to the invention, the light source may optionally have one or more of the following characteristics:

the rods have a thickness of between 0.1 micrometers (μιτι) and 2 micrometers, in particular between 1.4 μηι and 1.6 μηι, for example 1μηι; this makes it possible to increase the light emitting surface and confers a better light output to the light source;

the rods have a height of between 2 μηι and 10 μηι, for example 8 μηι; this makes it possible to increase the light emitting surface and confers a better light output to the light source;

the rods are separated from each other by a distance between 1 μηι and 35 μηπ, preferably between 3 μηι and 30 μηι, preferably between 3 μηι and 10 μηι;

the maximum of distance corresponds to a minimum of density in sticks; although this maximum distance is not limiting, it confers better results in terms of light output, namely the ratio of the optical power emitted on the electric power injected; the minimum of 1 μηι 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 3μηι; the efficiency reaches a particularly interesting value with a distance of at least 20 μηι;

the optimal interval, in terms of compromise with respect to the luminous efficiency and the luminous intensity, is between 20 μηι at 30μηι; this interval is however not limiting;

the light source comprises a substrate from which the rods extend; the light source comprises a connection means intended to be connected to a power supply, this connection means being arranged to supply electrically and independently the different transmission zones, or when it is the case the different subgroups; the light source can thus receive the power supply of the different emission zones from a single connection point;

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

the light source comprises at least as many anodes as emission zones, or emission zone portions when a transmission zone is arranged in several parts, each anode being arranged to be in contact with each rods of one and the same emission zone and / or part of the emission zone, in particular each anode being connected to one or more positive terminals of the connection means or each forming a positive terminal of the connection means; it is an example of a compact and simple embodiment of the connection of each emission zone or parts thereof, 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 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. Unless otherwise specified, when used for the arrangement of the luminous device, the terms "front", "rear", "lower", "upper", "side", "longitudinal", "transverse" refer to the meaning of light emission out of the luminous device.

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, among which:

Figure 1 is a longitudinal vertical section of a light device according to the invention;

FIG. 2 represents a schematic top view of the light rod source of the light device of FIG. 1;

Figure 3 shows a schematic sectional view of the light source of Figure 2;

FIG. 4 represents an alternative embodiment of the light source of FIG. 2;

FIG. 5 represents another variant embodiment of the light source of FIG. 2.

Note that these figures are schematic; the scales should not be taken into consideration between the different elements.

FIG. 1 illustrates an exemplary light device D of a vehicle according to the invention comprising a light module M. This light device D is a vehicle rear light capable of emitting a light beam, in particular a signaling beam F.

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

Inside this interior volume, is arranged the light module M. The latter comprises a light source S, which emits the r1 and r2 rays to form, in this example, the entire signaling beam F. As it will be detailed later, this light source S comprises different activatable emission zones selectively, that is to say that can be electrically powered or turned off independently depending on a received control signal.

The light module M comprises at least one connector C connected to the light source S and intended to be connected to a power supply K to electrically power the light source S, in particular via a single electrical harness J.

The light module M comprises a shaping optics O receiving the light r1, r2 emitted by the light source S and deviating them so as to give the beam F the characteristics of the signaling function. The shaping optics O may comprise a reflector, a combination of lenses, a combination of reflectors, or a combination of lenses and reflectors.

The closing lens G may comprise a blasting for diffusing the r1, r2 rays, received around an overall direction parallel to the overall direction of emission X of the signaling beam F

The emission zones of the light source S are detailed in FIGS. 2 and 3.

As illustrated in FIG. 3, the light source S, here shown partially and in section, comprises a substrate 10 from which sticks 11, 12 extend in a preferred direction.

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 can be obtained by crystalline growth on this substrate 10.

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

For example, these rods 11, 12 comprise a semiconductor material core capable of being doped with electrons, around which is formed a first layer of semiconductor material capable of having deficits in electrons, in this case sometimes referred to as 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 is an electroluminescent semiconductor element.

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

The rods 11, 12 are here at a distance of about 30 μηι and each have a height, taken from the nucleation layer 19 to their apex, of 2.5 μηι. Their thickness, which corresponds here to the width of the rods in FIG. 1, is 1 μηπ.

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

According to the present invention, the light source S is divided into several transmission zones 1, 2, corresponding to a distribution of the set of rods 11, 12.

In this example, there are two transmission areas 1, 2, a first transmission 1 and a second transmission zone.

According to the invention and in particular in this example, the first transmission zone 1 emits first rays r1 forming the light beam F and the second transmission zone emits second rays r2 carrying a communication signal.

In this example, the first light r1 r1 allow the realization of a reversing light and second r2 r2 allow the transmission of information, such as the distance to the vehicle, for example to a next vehicle.

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

The four 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 transmission zones 1, 2 can be independently supplied with electricity.

According to one embodiment of the invention, each anode is connected to one or more positive terminals of a connection means 20, intended to be connected to the positive terminal of a power source K of a vehicle. Similarly, the cathode 10 is connected to the negative terminal of the connection means 20, for example via an electrical conductor 40. The activation means therefore allows the power supply of each of these transmission areas 1, 2.

It is therefore possible to control this light source S, by selective activation of its transmission zones 1, 2, via the connection means 20.

The control can be achieved by a specific means separate from the light device D, or, as in this example, by a control device 29 integrated in the light device. The latter is connected on the one hand to the connection means 20 and on the other hand to the connector C. The connection means 20 is connected to each anode 25, 26 via electrical conductors 31, 32.

The control device 29 and the light source S are mounted on the same printed circuit board, not shown. The electrical conductors 31, 32, 40 are formed by electronic tracks of this printed circuit board. Likewise, other electronic tracks connect the connection means 20 to the control device 29.

The luminous efficiency of the light zones 1, 2 can be improved by depositing a reflective layer 17, 18 on the layer This reflective layer 17, 18, for example, is deposited on the nucleation layer 19 before growth of the rods, then holes are formed in this reflecting layer 17, 18, as well as in the nucleation layer, before growth. rods 11, 12 on the substrate 10.

The rods of the bright areas have in this example the characteristics below:

a thickness of 1.5 μηι,

a height of 8 μηπ,

a distance between each rod of between 2 and 100 μηπ.

The distance between each rod of the same substrate may be constant or variable.

As illustrated in FIG. 3, the light source may comprise a light converter 23 arranged above the rods 11, 12.

A light converter comprises at least one luminescent material adapted to absorb at least a portion of at least one excitation light emitted from a light source and to convert at least a portion of said absorbed excitation light into a light source. emission having a wavelength different from that of the excitation light.

For example, the converter 23 is a luminophore, which can be deposited on the top of the rods 11, 12. In FIG. 3, the rods are in flush contact with this phosphor layer 23. This layer can be arranged in a lower manner on the light source, so that the rods penetrate more or less into this layer.

It is thus possible to make the rods with a chemical composition for emitting light rays of a given wavelength.

In this example, the rods 11 of the first emission zone 1 and the rods 12 of the second emission zone 2 are identical, in particular in chemical composition. According to an alternative embodiment, the phosphor layer 23 does not have the same chemical composition above the first emission zone 1 as above the second emission zone 2.

The rods 11 of the first emission zone 1 emit light r1 rays of blue color when they are electrically powered. Above the first emission zone 1, the phosphor layer 23 has a composition for converting these light rays into r1 rays of white color.

The rods 12 of the second emission zone 2 emit r2 light rays of blue color when they are electrically powered. Above the second emission zone 2, the phosphor layer 23 has a composition for converting these light rays infrared r2 rays.

Thus, the first transmission area 1 allows the realization of a beam F performing a reversing light function. The communication signal corresponding to the r2 rays integrated in this beam, not being in the visible range, this beam is not altered.

According to another variant, the phosphor layer 23 has the same composition throughout the light source S. The phosphor layer 23 has a composition for converting the light rays of all the rods 11, 12 of the two zones. 1, 2, in r1 and r2 rays of white color. According to this variant, the radii r2 of the second emission zone 2 participate in the formation of the reversing light. However, as in this example the surface of the second emission zone 2 is less than one-tenth of the area of the first emission zone 1, the fluctuations generated by the signals emitted in the luminous flux of the reversing light will be less noticeable. .

In particular, thanks to the use of a rod source S, the second emission zone 2 may have a transmission area of less than 1 mm ² . Moreover, in one embodiment, particularly like this one, where the rays emitted to produce the communication signal are emitted with a wave color in the visible range, this makes it possible to increase the intensity and therefore the range of the signal, with less risk of harm to the human eye. In such a case, photoreceptors can be used to receive this signal.

When the driver engages the reverse, a control signal is sent to the control device 29. The latter then selects the supply rods 11 of the first transmission zone 1 via the connection means 20. At the same time, if a signal communication must be issued, for example to inform a vehicle behind the rear vehicle with this light device D, the control device 29 also triggers the supply rods 12 of the second transmission zone 2.

The transmission zones 1, 2 is independent and selective. For example, in the absence of recoil of the vehicle but if a communication signal must be transmitted, the control device 19 feeds only the rods 12 of the second transmission zone 2.

For the transmission of the communication signal, the control device 29 modulates the intensity and the frequency of the supply, in voltage and / or current, of the rods 12 of the second transmission zone 2.

The separation between the different emission zones 1, 2 can be achieved by simple activation or deactivation of these light zones, that is to say simply by the connection of the corresponding rods, for example by the positioning of the anodes 25, 26 .

Nevertheless, the light source may comprise, as illustrated in FIGS. 2 and 3, walls 21, opaque in this example, positioned between each of the emission zones 1, 2. The walls in particular make it possible to avoid a risk of "cross talk ". The phenomenon of "cross talk" is observed when the rods of a zone of emission emit light rays in the direction of a phosphor located above a neighboring emission zone, these light rays can then be converted by said phosphor. This may result in a parasitic light from said phosphor above the neighboring emission zone even though the rods of the neighboring emission zone are not electrically powered. The stray light can modify, among other things, the color of the desired beam or the shape of the beam or disturb the communication signal.

According to embodiments not shown, the optical separation of the emission zones could be achieved by diffusing or reflecting walls. When walls are reflective, it helps to strengthen the radiation emitted.

These walls 21, can be obtained by growth on the substrate. For example, it is possible to make deposits on the substrate 10 forming a grid corresponding to these light areas, and then to achieve a vertical crystalline growth to achieve these opaque walls 24. Then, the rods 11, 12 are made by growth with other materials.

FIG. 4 shows an alternative embodiment in which the light source S 'is also a rod source 11, 12 divided into two transmission zones 1, 2, controlled selectively by a control device (here not shown).

However, in this example, the light source comprises a plurality of second emission zones 2 distributed at the four corners of the light source S ".The first transmission zone 1 is continuous and has separation portions which separate the second transmission zones. emission 2 from each other.

Since the rods 12 of the second zone 2 are not permanently powered, the substrate under the second zone 2 will be used to homogeneously cool the first emission zone 1, and in particular the separation portions, especially in embodiments where the first transmission zone 1 is fed continuously. For example, the rods 11 and the first transmission zone 1 are arranged so that the latter emits rays of red color to perform a position of taillight function.

In order to minimize the disturbances in the rear position light beam, the rods 12 and the second emission zones 2 are arranged so that these second emission zones 2 emit non-visible rays, especially infrared rays.

Here, the sum of the surfaces of the second emission zones 2 is less than one-third of the total area of the emission zones 1, 2 of the light source S ".

Other positions on the light source S "could be chosen for the second emission zones 2.

According to other embodiments, not shown, the light source also comprises a plurality of first transmission zones, distributed alternately with the second transmission zones.

In this example, the other characteristics are similar to those of the example of FIGS. 2 and 3.

According to another variant embodiment illustrated in FIG. 5, the first emission zone 1 'and the second emission zone 2' of the light source S "are each divided into subgroups P1, P2, in which the transmission rods the corresponding emission zone is distributed For the sake of clarity, the rods have not been shown in this FIG.

Each subgroup P1, P2 is selectively activatable. This makes it possible to pixelate the emission zones 1 ', 2'. This can be used to adjust the photometry of each emission zone 1 ', 2', and independently.

For example, according to certain embodiments, this may be a means of making it possible to impart a certain shape to the light pattern forming on the light source S ", and thus to obtain, by projection or not, a light beam with a given photometry. .

Claims

1. A vehicle light device (D) comprising a light source (S; S '; S ") comprising electroluminescent rods (1 1, 12) of submillimetric dimensions, the rods being distributed in a first transmission zone (1) and in a second emission zone (2), each of these emission zones being independently activatable, said first emission zone being arranged to be able to emit light rays (r1, r2) participating in the formation of a light beam (F), and said second transmission area being arranged to be able to emit a communication signal.

2. Light device (D) according to claim 1, said light beam (F) fulfilling a given photometric function.

3. Luminous device (D) according to claim 1 or 2, wherein the first emission zone (1) and the second emission zone (2) are arranged to emit light rays of identical wavelengths. .

4. Light device (D) according to claim 3, wherein the second emission zone (2) has an area less than one-tenth of the sum of the areas of all the emission zones (1, 2) of said light source. (S).

5. Luminous device (D) according to claim 3 or 4, wherein the second emission zone (2) has an area less than 1 mm ² .

Light device (D) according to Claim 1 or 2, in which the first emission zone (1) and the second emission zone (2) are arranged in such a way as to emit light rays (M) and radiation. electromagnetic

(r2) of different wavelengths.

7. Luminous device (D) according to claim 6, wherein the second emission zone (2) is arranged to emit infrared rays.

The luminous device (D) according to claim 7, wherein the rods (2) of the second emission zone (2) emit blue light rays (r2) when electrically powered, and wherein said light source (S) comprises a phosphor layer (23) arranged on the rods to receive light rays of blue color, said phosphor layer having a composition such as to convert these light rays into infrared rays.

9. Luminous device (D) according to one of the preceding claims, wherein the rods (1 1) of the first emission zone (1) emit light rays (r2) of blue color when they are electrically powered, and wherein said light source (S) comprises a phosphor layer (23) arranged on the rods to receive blue light rays, said phosphor layer having a composition such as to convert these light rays into rays. bright of a white color.

10. Light device (D) according to claim 9, wherein the rods (1 1) of the first emission zone (1) and the rods (12) of the second emission zone (2) are identical.

1 1. Light device (D) according to one of claims 6 to 10, comprising a plurality of second transmission zones (2) separated from one another by portions of the first transmission zone (1) and / or by different first zones resignation.

12. Light device according to one of the preceding claims, wherein said light device is selected from a projector, a vehicle rear lamp, a fog light, a license plate lighting device, a direction indicator.

13. Light device according to one of the preceding claims, wherein said light device is a lighting device of the vehicle interior.

14. A method of controlling a light source of a vehicle light device (D), said light source (S, S ', S ") comprising electroluminescent rods (1 1, 12) of submillimeter dimensions, said method comprising the following steps:

a step of activating certain rods (1 1) distributed in a first emission zone (1) of the light source so as to emit light rays (r1) forming directly or after deviation a light beam (F) fulfilling a given photometric function,

- A step of activating some rods (12) distributed in a second emission zone (2) of the light source so as to emit a communication signal.

15. Control method according to claim 14, wherein the step of activating some rods (12) distributed in the second emission zone (2) is achieved by modulating the power supply rods of the second zone of program.

16. Control method according to claim 14 or 15, the method being implemented so as to drive a light device according to one of claims 1 to 13.