FR2957864A1 - Method for controlling power supply of e.g. bi-functional headlamp of motor vehicle, involves allocating power supply mode of headlamp, and recording power supply mode associated with lighting modes - Google Patents

Abstract

The method involves determining pertinent driving parameter e.g. distance, between a vehicle and a following vehicle, for lighting a vehicle, and defining multiple lighting modes. A power supply mode of a headlamp (10) is allocated to one of the lighting mode. The power supply mode associated to the lighting modes is recorded. A lighting controller (12) is arranged for receiving values related to parameters and generating supply voltage. An independent claim is also included for a device for controlling a power supply of a headlamp.

Description

DEVICE FOR CONTROLLING THE POWER OF A PROJECTOR

The invention relates to a device for controlling the power supply of a vehicle headlamp. The invention also relates to a lighting projector for a motor vehicle and a power control method of such a projector. The invention finds its application in the automotive field and, in particular, in the field of lighting for motor vehicles for the power supply of incandescent lamps or light-emitting diodes in vehicle lighting projectors. In the field of automotive lighting, there are different types of lighting function among which we find mainly: - low position lights, intensity and range. This function is mainly intended to signal the presence of the vehicle by average brightness and visibility; - dipped beam, or code, of greater intensity and range on the road generally around 70 meters. This function is mainly used at night. It is characterized by a light distribution having, at least in one area, a strong light gradient so as not to dazzle the drivers preceded or arriving in the opposite direction; - high beams, with a long range typically around 200 meters. This function is used to illuminate the road in the distance and allow the driver to understand the trajectory of the vehicle; - fog lights.

Currently, there are light projection devices, or projectors, which provide the code function and the road function. These projectors are usually called dual-function projectors. Such a dual-function projector comprises a light source emitting an identical luminous flux whatever the mode of operation (road or code). It generally comprises a removable cover capable of ensuring a cut-off of the light beam. This cover is, for example, a metal flap that can be in a first position or a second position. In the first position, the cache does not obscure the light beam produced by the light source, or lamp, of the projector. In the second position, the cache partially obscures the light beam produced by the projector lamp. In this second position, it is said that the cache performs a specific cut of the light beam, this specific cutoff corresponds to the cutoff of the light beam needed to obtain the code function. Thus, the lighting in code mode or in road mode differs in the presence or absence of the cut.

In current dual-function projectors, the light source may be a halogen lamp. This halogen lamp is usually powered by a fixed voltage, which is usually the nominal voltage of the lamp specified, by the lamp manufacturers, for each type of lamp. This nominal voltage is often the supply voltage for which the operation of the lamp fulfills the regulatory requirements. Lamp manufacturers, in addition to indicating a nominal voltage, indicate average lamp life. Typically, the life of an H7 type lamp is about 900 hours at 13.2V. However, it turns out in practice that the average life of the lamps is often significantly lower than that indicated by the manufacturers because of the voltage of the vehicle electrical system, which is often higher than the rated voltage of the lamp. At the end of its service life, a new lamp must be purchased and reinstalled in the projector. This operation is increasingly complicated to perform by the user, which can result in immobilization of the vehicle and an additional cost. There is therefore a need to increase the actual life of the lamps while maintaining satisfactory lighting performance. In addition, there is a need to reduce the energy consumed by a projector for vehicle lighting.

The invention aims to provide a solution to at least one of the needs previously expressed. For this purpose, provision is made according to the present invention for a method of controlling the power supply of a vehicle headlamp capable of providing road-based and / or code-based illumination, characterized in that it comprises the following steps for at least one of the code and route functions: - at least one driving parameter relevant to vehicle illumination is determined, - a plurality of illumination modes characterized by the value of this at least one parameter are defined, each mode of lighting is assigned a mode of supplying the projector, the mode of supply associated with each of the lighting modes is recorded in a memory.

Thus, it adapts the power mode of the projector according to lighting modes and therefore driving situations. Therefore, it modulates the energy consumption of the projector which allows to extend the life of the light sources and / or to reduce the CO2 emission of the projector according to driving situations.

According to a particular embodiment, each projector power mode corresponds to a given voltage applied to the projector and / or corresponds to a given intensity applied to the projector. Thus, according to the identified driving mode, the lighting is adapted by modulating the voltage and / or intensity applied to the projector.

It turned out that the voltage across the lamp directly impacts its life. Specifically, the higher the voltage, the longer the life of the lamp is low. For example, with a voltage of 13.2 volts, an H9 lamp has a lifetime of about 4.4 times less than that corresponding to a voltage of 11.78 volts, which is, in this case, the order of 1100 hours Moreover, the performance of a lamp is characterized mainly by its flow and luminance. These performances, flux and luminance, are functions of the voltage at the terminals of the lamp. Thus, the higher the voltage across the lamp, the higher the flux and the luminance. By way of example, considering the luminance: for a standard H9 type lamp, the luminance is of the order of 3400 cd / cm2 for a voltage at the lamp terminals of 13.2 volts and 3150 cd / cm2 for a voltage of 12.8 volts. In other words, the improvement in luminance is to the detriment of the life of the lamp. As part of the development of the present invention, it has been found that in existing projectors, because of the presence of the alternator at the terminals of the battery, the voltage generally rises considerably when the engine is running. This voltage rise typically results in switching from 13.2 volts to 14 volts or more. This rise in voltage in addition to causing overconsumption, tends to significantly reduce the life of the lamp.

In addition, more often than not, this overconsumption is not accompanied by comfort or driving safety significantly improved since satisfactory lighting is already obtained for less voltage. The invention is intended to solve the critical problem of excessive power consumption of automotive lighting halogen lamps by extending the lamp life, while ensuring adequate performance of the projectors under normal driving conditions and high performance in special conditions such as driving on the motorway, lighting in "rotating code" mode, or braking, for example.

The invention provides for adapting the voltage delivered to the lamp according to the driving mode while the projector operates in code or on the road. We therefore have several voltages for the same lighting function. The voltage delivered to the lamp is thus chosen so as to generate a satisfactory illumination while limiting superfluous lighting which would lead to overconsumption, by supplying the latter with a voltage lower than the maximum recommended voltage and, in as many cases as possible , lower than the voltage of the vehicle's on-board system. This voltage takes into account internal and external parameters to the vehicle. By way of example, if ambient light is present, a voltage lower than the maximum voltage is applied to generate adequate lighting. The consumption of the lamp is reduced. Its life is increased. In addition, the amount of CO2 emitted is also reduced. According to another particular embodiment, the projector comprises a plurality of light sources and each projector power mode defines the activation or deactivation of at least one light source independently of the other light sources. Thus, according to the driving situation, a lighting mode is determined and the lighting is adapted by modulating the distribution of the activated light sources and the deactivated light sources. This modulates the amount of energy consumed by the projector and consequently the CO2 emission induced by the lighting. In a particular variant embodiment, each projector power mode defines the activation or deactivation of each of the sources independently of the activation and deactivation of the other light sources. It is therefore possible to adapt the consumption of the projector very precisely. Depending on the distribution and the number of activated sources and non-activated sources, it is also possible to define a large number of lights generated by the projector. According to a particularly advantageous variant, the illumination provided by the projector generates a luminous pattern and a luminous intensity and the modes of supply are defined so that the pattern is substantially identical for at least a plurality of modes of supply and so that for this plurality of power modes the light intensity varies from one power mode to another. Thus, it is expected that in a power mode the deactivated sources and the activated sources are distributed so as not to show variation of the pattern. The deactivation of certain light sources does not result in black or dimly lit areas. The driver's perception of the generated pattern therefore remains constant regardless of the driving style. On the other hand, beam intensity varies from one driving mode to another. It is thus possible to significantly reduce the power consumed by the projector without greatly disturbing the driver. Advantageously, the perception of the motive also remains constant for the drivers of other vehicles or for pedestrians. According to a particular variant embodiment, there is provided a method in which the headlight comprises a plurality of light sources and in which each projector power mode defines the voltage or the intensity applied respectively to each of the sources. Optionally, the invention further comprises at least any of the following features: the projector light sources are taken from incandescent lamps, light emitting diodes or modules comprising a plurality of light-emitting diodes or a plurality of of lamps. said at least one parameter comprises a parameter internal to the vehicle selected from the following parameters: a vehicle speed, navigation data, a speed of the vehicle engine, the speed of rotation of a vehicle steering wheel, the activation of windscreen wipers and fog lamps, an acceleration value, a speed or an angle of operation of a brake or acceleration pedal, the engagement of a command actuated by the driver, for example the choice of the "Economic" mode. said at least one parameter comprises a parameter external to the vehicle chosen from among the following parameters: ambient brightness, brightness of a public lighting, brightness of natural lighting, degree of pollution (with respect to one or more molecules). said at least one parameter comprises a parameter external to the vehicle chosen from among the following parameters: the density of the traffic, the number of vehicles in a given perimeter, the distance with respect to a vehicle tracked, the relative speed and / or the acceleration in relation to a tracked vehicle, a follower vehicle or a crossover vehicle, the color of a marking line on the ground, the meaning of a sign, the presence of an obstacle, the arrival at a crossing or a roundabout, the presence of an urban environment, the presence of public lighting, the detection of an obstacle, the presence of a red light or the presence of fog, rain, snow or smoke , the detection of an obstacle. wherein said at least one parameter includes a parameter that translates a traffic density, wherein the traffic density is determined by navigation data reflecting the traffic density. For example, it is expected that a vehicle equipped with a navigation system receives information indicating that the vehicle is located in a traffic jam. The device then identifies that the vehicle is in a traffic jam mode and then controls a decrease in the power applied to the projector. Alternatively, the traffic density is determined by navigation data reflecting the speed of the vehicle combined with at least one sub-parameter taken from: the distance with respect to a vehicle tracked, the number of vehicles within a given perimeter, navigation data traffic density. For example, the traffic jam mode is identified provided that the data from the navigation system detects a traffic jam and provided that the speed of the vehicle is less than 90 km / h. Thus, this identification of the driving mode can be subject to the verification of another parameter such as the speed of the vehicle. ù to assign the supply voltages or to define the number and distribution of the activated and deactivated sources, a combination of the following parameters is considered at least: vehicle speed and ambient brightness. These parameters are indeed particularly relevant for establishing a lighting strategy. for each of the code and route functions, several lighting modes are defined. In a nonlimiting manner, each lighting mode is characterized by the values of at least two parameters. when the vehicle is used, the following steps are performed: values relative to said parameter are received; one of the plurality of lighting modes identifies the lighting mode corresponding to these values; a mode of supplying the projector according to said lighting mode is determined. For example, the supply voltage is increased or the number of activated light sources is increased as a function of an increase in the speed of the vehicle and / or as a function of a decrease in ambient brightness and / or as a function of an increase of a rotation angle of the steering wheel. the values relating to said parameter are derived from one or more sensors taken from the following sensors: a radar, a lidar, a camera. the camera is configured to detect at least one of: the number of vehicles in the vicinity of said vehicle, the distance between said vehicle and at least one vehicle tracked, the absolute speed of the vehicle equipped with the camera, the relative speed and / or acceleration with respect to the vehicle tracked, a follower vehicle or a crossover vehicle. - the color of a marking line on the ground, - the meaning of a sign, - the intensity of ambient light, - the presence of an urban environment, - the presence of street lamps, - an obstacle - the ignition of a stop light of a vehicle followed. Preferably, the camera is located at the front of the vehicle. Advantageously, the same camera can be configured to detect several of the driving modes described above. Alternatively or cumulatively, the parameter or parameters detected with the sound camera combined with other parameters not derived from the camera such as the speed of rotation of the wheels, navigation data etc. This allows, when setting the device, to accurately define a large number of driving modes each corresponding to a lighting mode. In the use of the invention, this also makes it possible to increase the confidence coefficient associated with the driving mode identified during the driving phase. The use of a camera is particularly advantageous since it has a limited cost. This cost is further reduced in the case where the camera provides functions independent of those required in the context of the present invention. Advantageously, the power supply modes are defined by performing the following steps: a desired lifetime for the projector and / or a maximum desired energy consumption of the projector for a given duration of use of the projector are defined, a predetermined driving profile characterized by a relative duration of use of the projector in each of the lighting modes, it is calculated for each lighting mode a power mode so that with this power mode the projector ensures satisfactory lighting for this lighting mode while having a life time close to the desired life and / or while inducing an energy consumption close to the maximum energy consumption desired for use corresponding to the predetermined driving profile. Thus, identifying lighting modes that do not require too powerful lighting, reduces unnecessary consumption and / or increases the life of the projector lamp. Advantageously, it is identified whether the actual driving profile of the driver is moving beyond a certain threshold of the predetermined driving profile. If this is the case, then for each lighting mode, a new power mode is recalculated. This new power mode is recalculated so that with this new power mode, the life of the projector and / or the energy consumption of the projector, and therefore the emission of 002 remains substantially constant for this profile. driving behavior. According to another object of the invention, there is provided a device for controlling the power supply of a vehicle headlamp capable of providing road-based and / or code-based illumination, characterized in that, for at least one one of the code and route functions, it is arranged to: - receive values relating to at least one parameter that is relevant for the lighting of the vehicle, - identify, from among a plurality of lighting modes, a lighting mode corresponding to these values, - determine a power supply mode of the projector according to the lighting mode identified. In the case where the projector comprises a single lamp, the device according to the invention thus makes it possible to supply this lamp with a voltage which is relevant for the lighting mode of the current driving situation. This relevant voltage is high enough to provide satisfactory lighting and sufficiently limited to not generate unnecessary lighting. The invention thus reduces the consumption of the projector and thereby increase the life of the lamp, while ensuring satisfactory lighting conditions.

In the case where the headlight comprises a plurality of light sources such as light-emitting diodes, the device according to the invention makes it possible to activate a number of sources that are relevant for the lighting mode of the current driving situation. This number of sources is high enough to provide satisfactory lighting and sufficiently limited to not generate unnecessary lighting.

The invention thus makes it possible to reduce the consumption of the headlamp and thereby reduce the emission of CO2 while ensuring satisfactory lighting conditions. Optionally, the device according to the invention further comprises at least any of the following features: the device comprises at least one of the following means configured to receive the at least one parameter relevant for the illumination of the vehicle: means for detecting the number of vehicles in the vicinity of said vehicle; means for detecting the distance between said vehicle and at least one vehicle followed; means for detecting the absolute speed of said vehicle; detecting the relative speed and / or acceleration of said vehicle with respect to a tracked vehicle, a follower vehicle or a cross vehicle, - means for detecting the color of a marking line on the ground, - detection means the meaning of a sign, - means for detecting and measuring the ambient luminosity, - means for detecting the presence of an urban environment, - means for detecting the presence of street lamps, means for detecting an obstacle, means for detecting the ignition of brake lights of a vehicle followed. said means comprise a camera arranged to receive the at least one relevant parameter for illuminating the vehicle. alternatively or additionally to the presence of a camera, the device comprises a radar or lidar configured to receive the at least one relevant parameter for the lighting of the vehicle, the parameter being taken from the following parameters: the number of vehicles in the vicinity of said vehicle, - the detection of a vehicle followed, - the distance to one between said vehicle and a vehicle followed, - the relative speed and / or acceleration with respect to the vehicle being tracked, a follower vehicle or a crossed vehicle, - the presence of an obstacle. said means comprise a vehicle location system and a traffic data reception system transmitted by a remote traffic observation center. the device comprises a lighting controller arranged to receive the values relating to the parameter and to generate the supply voltage. the device is arranged to generate a supply voltage in the form of a pulse width modulated signal (PWM). the lighting controller comprises an electronic control card intended to be implanted in the projector. Where the device comprises a switch configured to disable the controller if the road function is engaged by the driver. It may be that the driver needs a powerful light whatever the driving situation. In this case, if it manually switches the high beam, adaptation of the supply voltage that provides the invention does not occur. The projector is powered by the voltage from the battery, itself powered by the alternator. The switch can also interrupt the computer if the driver acts on the brake control allowing the direct supply of the lamp by the edge voltage. A usage profile of the vehicle and its projectors is defined by the manufacturer. Depending on the lifetime or target consumption, this makes it possible to calculate the maximum levels of the different voltages. In the case where the driver of the vehicle does not follow the profile defined by the manufacturer, a lighting calculator modifies the levels of the voltages to guarantee the lifetime or the target consumption. For example, if the computer detects that the driving mode is 60% according to AFS and route, it will adjust the different voltages of the projectors to exceed for example 1000h of life for the lamp. The lighting computer, often positioned in the central controller (body controller), takes into account all the external and internal parameters of the vehicle (navigation, external lighting, street lighting, speed, engine speed) as well as the wishes of the driver (Driving mode and "Economy" consumption), to generate the optimum PWM supply voltage of the lamps so as to improve the performance if necessary and / or to reduce the emission of 002 of the vehicle to reach only the regulatory level of lighting. In the context of the invention, there is also provided a vehicle lighting projector comprising a power control device according to the present invention. This projector is able to receive at least one light source. Optionally, the projector according to the invention further comprises at least any of the following features: it comprises a plurality of lighting lamps. it comprises at least one lamp dedicated to only one of the road or code functions. it comprises a plurality of light sources and in which the device is arranged to control, according to the identified lighting mode, the activation and deactivation of at least one light source taken from the plurality of sources of light and regardless of the activation and deactivation of other light sources. the device and the distribution of the light sources are configured so that, for at least a plurality of lighting modes, the light intensity generated by the projector varies and the shape of the light pattern generated by the projector remains substantially constant; one lighting mode to another. the light sources are individual light emitting diodes or modules comprising a plurality of light-emitting diodes. the projector comprises at least one lamp dedicated to only one of the road or code functions.

Other features, objects and advantages of the present invention will appear on reading the detailed description which follows, and with reference to the appended drawings, given by way of non-limiting examples and in which: - Figure 1 shows schematically a classic motor vehicle headlamp. FIG. 2 schematically represents a projector and an example of a device for supplying a projector lamp according to the invention. FIG. 3 represents a table illustrating an example of definition of lighting modes with the supply voltages associated with them. - Figures 4 and 5 each show schematically a projector and another example of a projector lamp supply device according to the invention in which a plurality of sensors are used to determine the power mode of the projector. - Figure 6 shows four elementary beams respectively from a light source. - Figure 7 shows two complex beams respectively from four light sources and two light sources. In Figure 1, there is shown an example of a projector 10 of a motor vehicle. This projector 10 generally comprises a housing 1 closed by a protective glass 2. The projector 10 comprises, inside the housing, a lighting module 3, for example an elliptical module. The lighting module 3 comprises, in particular, a light source 4, also called a lamp, a reflector 5 adapted to reflect the light towards the protective glass, a lens 6 capable of projecting light, a removable cover 7 and means of illumination. supply 8 of the lamp.

With reference to FIGS. 2 and 3, an exemplary implementation of the invention will now be described. Figure 2 shows the main elements of an example of a power control device associated with a projector 10 equipped with a lamp 14. The device comprises a battery 11 configured to power the projector 10. The battery 11 also powers A lighting controller 12. The function of the lighting controller, as will be detailed later, is to provide a supply voltage of the lamp 14 which is adapted to the driving situation so as to generate sufficient illumination while suppressing unnecessary lighting. The controller ultimately reduces lamp consumption, limits the emission of 002, and extends the life of the lamp.

The circuit of FIG. 2 also comprises a direct connection between the battery 11 and the projector 10. A switch 13 is arranged to interrupt the lighting controller 12 when it is closed. When the switch 13 is closed, the projector 10 is directly powered by the battery 11. The switch 13 is connected to a control operable by the user. Thus, when the latter wishes to use the projector 10 without adjusting the voltage, he activates this command. Such may be the case for making a lighthouse call. In the illustrated example the voltage is then maximum and is of the order of 13.2 volts (voltage of the vehicle electrical network, generally close to 13.2 V).

It is expected that the user is open by default. When the switch 13 is open, the voltage supplied by the battery 11 passes through the lighting controller 12. In a characteristic manner to the invention, the control device is equipped with a memory which comprises a database. This database contains for at least the code function or the route function several lighting modes.

Advantageously, it contains several lighting modes for each of these two functions. It is specified here that the lighting modes are distinct from the code and road lighting functions. A lighting mode is typically defined by at least one value or range of values of a vehicle-related parameter. More precisely, this parameter is a relevant parameter for the illumination of the vehicle. It can relate to a parameter internal to the vehicle and be chosen from the following parameters in particular: a vehicle speed, navigation data, a speed of the vehicle engine, the speed of rotation of a vehicle steering wheel, the activation of windscreen wipers and fog lamps, the activation of a command operable by the driver, for example the choice of the "Economic" mode and / or the activation of the brake pedal. The engagement of a command by the driver may concern at least the choice of a mode of driving having a direct relation with a reduction of the consumption and the emission of CO2 - normal, sport or economic mode of driving, the command brake and the call of lighthouses. It can also relate to a parameter external to the vehicle. It then reflects the environment of the vehicle and can be chosen from the following parameters in particular: ambient brightness, brightness of a public lighting, brightness of natural lighting.

The external parameter may also reflect: the number of vehicles within a given perimeter, the distance from a vehicle tracked, the relative speed and / or acceleration relative to a tracked vehicle, a follower vehicle or a crossover vehicle, the the color of a marking line on the ground, the meaning of a sign, the presence of an obstacle, the arrival at a crossing or roundabout, the presence of an urban environment, the presence of 'public lighting, the presence of a red light, the presence of fog, rain, snow or smoke, the detection of an obstacle. Advantageously, a lighting mode is characterized by several parameters. Since these parameters return to characterize a driving situation, the more the number of parameters is important, the more precisely the driving situation is characterized and the better will be the relevance of the supply supplied to the lamp. Thus, the traffic density can be determined by navigation data reflecting the traffic density or by the speed of the vehicle combined with at least one sub-parameter taken from: the distance with respect to a tracked vehicle, the number of vehicles in a defined perimeter, navigation data reflecting traffic density. The table in Figure 3 illustrates different lighting modes, whose names appear on the first row of each column from the second column. The parameters are listed in the first column. The cells in the table indicate the values of the parameters that characterize the lighting mode of the column in question. In this example, lighting below a first threshold indicates that it is dark, while lighting between thresholds 1 and 2 indicates dusk. The frequency sensor around 100 Hz detects the presence of artificial light. To simplify the example, the parameters relating to the steering wheel speed, the navigation information and the acceleration and braking information were not taken into account. Preferably, it imposes on the power supply of the projector a time delay not to react to changes too short of detected light modes so as not to disturb the driver and other vehicles. In the example of FIG. 3, the voltage relative to a detected mode is only applied if the values correspond to this mode for more than five seconds, except for the braking command for which the reaction time is immediate. Thus, it appears for example that the controller has in its memory, for the code function, a lighting mode entitled "City mode night low speed." This lighting mode is characterized by the following parameters: ambient lighting detected below a threshold 1, a speed of less than 30Km / h and no steering wheel speed. It also appears that the controller has in its memory, for the road function, a lighting mode entitled "reduced speed road mode night". This lighting mode is characterized by the following parameters: ambient lighting detected below a threshold 1, a speed of between 50 and 70 km / h and no steering wheel speed. In the illustrated example, the controller contains different distinct lighting modes, each reflecting a specific driving situation. The lighting modes illustrated in Figure 3, are described below: "City mode, night, low speed": driving less than 30 km / h with ambient lighting below threshold 1 and detecting artificial lighting, the voltage applied to the lamp is then 10.5 V. "City mode, night, normal speed": when traveling between 30 and 50 km / h with ambient lighting below threshold 1 and detecting artificial lighting, the voltage applied to the lamp is then 11.2 V. "City mode, twilight, normal speed": rolling less than 50 km / h with ambient lighting below threshold 2 and without detecting artificial lighting, the applied voltage the lamp is then 10.5 V. "Mode code countryside, twilight, reduced speed": rolling between 50 and 70 km / h with ambient lighting below threshold 2 and without detecting artificial lighting, the applied voltage at the lamp is then 11.2 V. 'Mode code campaign, night, lives reduced esse ": when traveling between 50 and 70 km / h with ambient lighting below threshold 1 and without detecting artificial lighting, the voltage applied to the lamp is 12.2 V." Country code mode, night, normal speed ",: when traveling between 70 and 90 Km / h with ambient lighting below threshold 1 and without detecting artificial lighting, the voltage applied to the lamp is 12.8 V." Code mode countryside, twilight , "normal speed": when traveling between 70 and 90 km / h with ambient lighting below threshold 2 and without detecting artificial lighting, the voltage applied to the lamp is 12.2 V. "Road mode, dusk, normal speed ": when traveling between 70 and 90 km / h with ambient lighting below threshold 2 and without detecting artificial lighting, the voltage applied to the lamp is 12.2 V." Mode route, night, speed reduced ": traveling between 50 and 70 km / h with ambient lighting below uil 1 and without detecting artificial lighting the voltage applied to the lamp is then 12.8 V. "Road mode, night, normal speed": driving over 70 km / h with ambient lighting below threshold 1 and without detection of artificial lighting, the voltage applied to the lamp is then 13.2 V. "Fast route code mode": while traveling over 100 Km / h with ambient lighting below threshold 1 and without detecting lighting artificial, the voltage applied to the lamp is then 12.8 V. "Highway code mode": rolling over 130 km / h with ambient lighting below threshold 1 and without detecting artificial lighting, the voltage applied to the lamp is then 13.2 V. "Normal speed DBL mode": when traveling over 70 Km / h with ambient lighting below threshold 1 and without detecting artificial lighting, the voltage applied to the lamp is then 13.2 V as soon as the steering wheel movement is detected. "Headlamp call": The driver makes a headlamp call manually, which interrupts the lighting calculator. This manual control can in a variant also pass through the computer which then generates a form factor PWM signal suitable for generating 13.2V across the lamp.

Also typically, a voltage is associated with each of these lighting modes. The control device also includes in memory this voltage. To take again the two examples mentioned above, voltages of 10.5 volts and 12.8 volts are respectively associated with the modes "city mode low speed night" and "mode road speed reduced night".

The controller is configured to receive values relating to the parameters characterizing the lighting modes. It then identifies, among the plurality of lighting modes, the lighting mode corresponding to these values. It then determines the power mode associated with this lighting mode. In the case where the projector's light source is a lamp, each power mode will preferably correspond to a voltage applied to the lamp. Finally, it controls the supply of the projector lamp with this voltage. Thus, the voltage applied to the projector does not depend on the route function or code, but depends on a plurality of lighting modes each corresponding to a driving situation.

In a particularly advantageous manner, the parameter or parameters reflect a traffic density. For example, it is expected that a vehicle equipped with a navigation system receives information indicating that the vehicle is located in a traffic jam. The device then identifies that the vehicle is in a traffic jam mode and then controls a decrease in the power applied to the projector. Preferably, this identification of the driving mode can be subordinated to the verification of another parameter such as the speed of the vehicle. For example, the traffic jam mode is identified provided that the data from the navigation system detect a traffic jam and provided that the speed of the vehicle is less than 90 Km / h. Thus, the invention reduces the voltage power supply or the number of light sources activated when a bottling situation is detected. The life of the lamp is increased and / or the CO2 emission is reduced without significantly reducing safety. Indeed, in a traffic jam situation the light intensity can be attenuated since the speeds are reduced and the high concentration of vehicle contributes to strongly illuminate the bottling zone. The voltage associated with each of the lighting modes is determined so as to provide effective lighting in the driving situation corresponding to the lighting mode and so as to limit the consumption of the projector. First, a desired lifetime for the lamp is defined. This life depends closely on the indications given by the lamp manufacturer. A predetermined driving profile is then defined. This predetermined driving profile is characterized by a relative duration of use of the projector in each of the driving situations associated with a lighting mode. Advantageously, it corresponds to an average use of the vehicles intended to receive the device. For example, it can be established that, according to this predetermined driving profile, the headlamp will operate 10% of the time in a driving situation corresponding to a first lighting mode, 20% of the time in a driving situation corresponding to a second mode of driving. 30% of the time in a driving situation corresponding to a third mode of illumination and 40% of the time in a driving situation corresponding to a fourth mode of illumination. In practice, the predetermined driving profile and the target life will be defined by the manufacturer to adapt the levels of the different voltages.

For each lighting mode, a supply voltage is calculated so that with this voltage: the lamp provides satisfactory lighting for this lighting mode, the lamp has a life time close to the desired lifetime when the projector is used according to the predetermined driving profile. The supply voltage supplied to the projector is lower than the voltage delivered by the battery for all lighting modes that do not require maximum light output. This lowering of the voltage operated by the controller makes it possible to limit the consumption of the lamp. The CO2 emission is reduced. In addition, the life of the lamp is increased. In the case where the driver of the vehicle does not follow the predetermined driving profile defined by the manufacturer, the lighting computer automatically modifies the voltages so as to still achieve the life expectancy with this real driving profile of the driver .

Additional features of the device will now be detailed. The device comprises power supply means and the lighting controller. The latter can be located outside the projector and can be integrated if necessary into another electronic box such as the "body controller", to control the power of the lamps of the vehicle. It includes a microcontroller and a voltage chopper controlled by the microcontroller. In this case, the lamp is powered directly by the vehicle lighting controller, with a pulse width modulated signal also called time-modulated signal and often referred to as the PWM (Pulse Width Modulation) acronym.

The lighting controller 12 comprises an electronic control card intended to be implanted in the body controller. It receives parameter values from a number of vehicle sensors: vehicle speed sensor, ambient light sensor, steering wheel angle sensor, navigation system, acceleration sensor, dash sensor. a pedal or command etc. He deduces the lighting mode corresponding to the driving situation and controls the application of the voltage associated with this mode. Particularly advantageously, the vehicle is equipped with a sensor camera for identifying the driving mode and determining the voltage to be applied to the headlamp. More precisely, the camera can be configured to detect: the number of vehicles near the vehicle equipped with the camera. A bottling situation can thus be detected. The voltage supplying the projector can then be reduced. - the distance between the vehicle equipped with the camera and at least one vehicle followed. The closer the vehicle is, the lower the voltage to the projector. relative speed and / or acceleration with respect to the vehicle being tracked, a follower vehicle or a crossover vehicle. - the absolute speed of the vehicle equipped with the camera. - the color of a marking line on the ground. If a marking line announces work, then the voltage supplying the projector is temporarily increased so as to reinforce the lighting in the work areas which are often particularly accidentogenic. - the meaning of a sign. If a sign indicating a crossing or a roundabout is detected, then the device controls a lowering of the voltage supplying the projector. The vehicle equipped with the camera then arrives at the intersection or roundabout without dazzling other vehicles. Alternatively or cumulatively to the use of a camera, it is also possible that the device identifies the arrival of the vehicle at a crossing or a roundabout through a navigation system. - ambient lighting and / or the presence of streetlights and / or the presence of an urban environment and / or the presence of public lighting. The camera thus makes it possible to dispense with a light sensor. - the presence of a red light. - the presence of disturbances of visibility such as fog, rain, snow or smoke. Advantageously, the camera also determines the density of this phenomenon. Thus, if a significant fog is detected, the device controls an increase in the light intensity generated by the projector. - a barrier. In the event of obstacle detection on the pavement for example, the invention may control an increase in the tension of the projector so as to temporarily improve the visibility of the obstacle. - the brake light ignition of a vehicle followed. Ignition of brake lights by the car followed may announce an obstacle or danger located in front of the vehicle equipped with the invention. The tension of the projector is then increased so as to improve the visibility in order to determine the cause of the braking of the vehicle followed. Preferably, the camera is located at the front of the vehicle. Depending on the nature of the detection to be made, the camera can be very basic or be equipped with color recognition means and / or obstacle recognition means, signaling panels, etc.

The use of a camera is particularly advantageous since it involves a limited cost. This cost is further reduced in the case where the camera provides functions independent of those required in the context of the present invention. Advantageously, the same camera can be configured to detect several of the modes of conduct described above. Alternatively or cumulatively, the parameter or parameters detected with the camera are combined with other parameters such as the speed of rotation of the wheels, navigation data etc. This allows, when creating the system, to accurately define a large number of driving modes. In the use of the invention, this also makes it possible to increase the confidence coefficient associated with the driving mode identified during the driving phase. In the example illustrated in FIG. 4, the voltage of the projector 41 is controlled by a control unit 42 which collects the data coming from several sensors 43, 44, 45. In this example, these data come from an illumination sensor 43 , a speed sensor 44 and a radar 45 measuring the presence of a vehicle tracking near the equipped vehicle or measuring the distance between the equipped vehicle and a vehicle followed. The control unit 42 combines the data from these sensors to determine the driving mode in which the vehicle is located so as to determine the supply voltage to be applied to the projector 41.

For example: if the illumination sensor 43 detects a street light and the speed sensor 44 identifies that the speed of the vehicle is not zero, then the control unit 42 applies a voltage of 12 volts to the projector 41. if the illumination sensor 43 detects an urban lighting and the speed sensor 44 identifies that the speed of the vehicle is zero, then the control unit 42 applies a voltage of 0 volts to the projector 41. if the illumination sensor 43 does not detect external lighting and that the speed sensor 44 identifies that the speed of the vehicle is zero, then the control unit 42 applies a voltage of 12 volts to the projector 41. if the radar 45 detects a vehicle followed at near the equipped vehicle, then the control unit 42 applies a voltage of 12 volts to the projector 41. Advantageously, the speed sensor 44 measures the speed of rotation of the wheels. Advantageously, the radar 45 is a cruise control radar. This radar 45 therefore has an additional function to that of controlling the lighting. The implementation of the invention on a vehicle therefore does not require additional radar, which limits the costs.

In the example illustrated in Figure 5, the control unit 42 controls the voltage of the projector 51 providing a low beam function also called code lights or designated by its English term low beam. In addition to collecting data from an illumination sensor 43 and a speed sensor 44, the control unit 42 collects data from a second projector 52 which provides a beam function also designated lighthouse or designated by its English word high beam. The control unit 42 is configured to identify whether the dipped beam is activated at the same time as the high beam. If this is the case, the control unit 42 lowers the voltage applied to the projector 51 of dipped beam at 12 volts. Thus, the light near the vehicle is reduced which is very detrimental to the safety and comfort of driving since the high beam is activated. The energy consumption is then reduced and the life of the light source of the dipped beam headlamp 51 is lengthened. This example can of course be combined with the previous example using a radar 45 to determine the driving mode. Preferably, the device is arranged to detect whether a high density of vehicles in the field of the camera is located on the left or right of the vehicle. If this high density of vehicles is located on the right, then the device deduces that the equipped vehicle is located in the traffic jam. The device then identifies a lighting mode corresponding to a traffic jam. The supply voltage of the projector is therefore reduced. If this high density of vehicles is located on the left, then the device deduces that these vehicles go in the opposite direction to that of the equipped vehicle. The latter is then not located in the traffic jam and the identified lighting mode does not correspond to a traffic jam. Preferably, other parameters are analyzed to determine whether or not the equipped vehicle is plunged into the traffic jam. These parameters may for example seek to identify, based on displacements or relative speeds, whether the vehicles are in the same direction as the equipped vehicle. This traffic jam detection is valid for countries that drive on the right. In order to configure a vehicle equipped with the present invention in countries operating on the left-hand side, there is also a command to reverse the detection of the traffic density: if a high density of vehicles is located on the left, then the device in deduce that the equipped vehicle is located in the traffic jam. The device then identifies a lighting mode corresponding to a traffic jam. The supply voltage of the projector is therefore reduced. In a particularly advantageous embodiment, the projector comprises a plurality of light sources. Each light source may be an incandescent lamp or, preferably, a light-emitting diode or a module comprising a plurality of light-emitting diodes or a plurality of lamps. The device according to the invention is configured to control, according to the identified lighting mode, the activation and deactivation of at least one light source taken from the plurality of light sources and independently of the activation and deactivation of other light sources. Thus, depending on the driving situation, the lighting generated by the projector is adapted by modulating the distribution of the activated light sources and the deactivated light sources. Energy consumption and CO2 emissions are therefore reduced. In a particular embodiment, at least one projector power mode defines the activation or deactivation of each of the sources independently of the other light sources. In order to limit the complexity of the device, it is expected that several light sources belong to the same module and can be activated and deactivated in a common manner. This is particularly advantageous when the projector comprises a high number of light-emitting diodes. Several light-emitting diodes are then grouped together to form the same module, the device controlling the simultaneous activation or deactivation of all the light-emitting diodes of the module.

Advantageously, the device and the distribution of the light sources are configured so that, for at least a plurality of lighting modes, the light intensity generated by the projector varies and the shape of the light pattern generated by the projector remains substantially constant from one lighting mode to another.

Thus, it is expected that in a power mode the deactivated sources and the activated sources are distributed so as not to show variation of the pattern. The deactivation of certain light sources does not result in black or dimly lit areas. The driver's perception of the generated pattern therefore remains constant regardless of the driving style. On the other hand, beam intensity varies from one driving mode to another. It is thus possible to significantly reduce the power consumed by the projector without greatly disturbing the driver. Advantageously, the perception of the motive also remains constant for the drivers of other vehicles or for pedestrians. This embodiment with adaptation of the lighting by modulation of the number and / or distribution of the light sources is applicable to both light sources consisting of lamps and light-emitting diodes or modules formed of light-emitting diodes. Figures 6 and 7 illustrate this adaptation of the lighting by modulation of the activation or deactivation of lighting sources.

FIG. 6 shows the patterns 61, 62, 63, 64 of four elementary beams each generated by a light source 81, 82, 83, 84. Each light source 81, 82, 83, 84 is a lamp or a light-emitting diode or a module formed of one or more light-emitting diodes or a module formed of one or more lamps.

The axes 68 and 69 respectively represent the horizon line and the vertical. The center defined by these axes 68, 69 is located at the front of the vehicle equipped with the present invention. The lines inside the patterns are lines of light intensity iso and thus reflect the areas of the same light intensity. The source S1 generates an elementary beam whose pattern bears the reference 61 and whose light intensity is almost zero above the horizon line. This type of beam is usually referred to as a horizontal cut beam. It avoids dazzling oncoming drivers. This beam can illuminate the center of the road. As is clear from FIG. 6, the source S2 generates an elementary beam whose pattern 62 is substantially identical to the pattern 61 of the beam generated by the source S1. The source S3 generates an elementary beam whose pattern 63 has an oblique cut along the axis 67. This beam is concentrated around the axis 68 formed by the intersection of the horizon line and the vertical 69. It avoids to dazzle the oncoming drivers on the left and illuminates an area 67 located above the horizon line and on the right. As is clear from FIG. 6, the source S4 generates an elementary beam whose pattern 64 is substantially identical to the pattern 63 of the beam generated by the source S3.

FIG. 7 represents the pattern 71 of a complex beam obtained by activating the sources S1, S2, S3 and S4. The pattern 71 of this complex beam is formed by the superimposition of the patterns 61, 62, 63, 64 of each of the elementary beams. It thus combines the characteristics of each of the patterns 61, 62, 63, 64 of these elementary beams. In particular, we find the illuminating zone 67 below the horizon line on the left and generated by the elementary beams of the sources S1 and S2. There is also the area 65 illuminating above the horizon line and on the right and generated by the elementary beams of the sources S3 and S4. Figure 7 shows a complex beam generated by sources S2 and S4 only. The pattern 72 of this complex beam corresponds to the superposition of the patterns 62, 64 only. The pattern 72 is very substantially identical to the pattern 71. Notably, there is the illuminating area 67 below the horizon line on the left and the area 65 illuminating above the horizon line and on the right. By deactivating the sources S1 and S3, therefore, the generated pattern is not significantly modified. In particular, there are no areas that become unlit due to the deactivation of sources 1 and 3. The driver of the equipped vehicle is therefore not disturbed. Other drivers and pedestrians are also not disturbed. In order to obtain the beam of the pattern 72, half the light sources are needed to obtain the pattern 71 beam. The energy consumption and the CO2 emission are therefore considerably reduced.

This reduction in consumption is accompanied by a decrease in light intensity. This decrease results in a lower density of light intensity iso lines on the pattern 72 than on the pattern 71. This drop in light intensity is however not detrimental in many driving situations. As explained in detail above, the device object of the present invention identifies these driving situations and adapts accordingly the power mode of the projector to maintain proper lighting while reducing energy consumption. In an alternative embodiment, it will be noted that, depending on the identified lighting mode, the voltage and / or the intensity applied to the source can both be adapted and the distribution and / or the number of activated sources. A non-limiting example will now be detailed to facilitate the understanding of the invention. To show how to increase the life of a lamp according to the voltage of the same lamp, it must be remembered that the life of a lamp varies with the power minus 13 of the voltage at these terminals. Consider a bi-halogen projector itself equipped with an H9 lamp and used 10% of the time on fast road (speed greater than 100 km / h), 10% of the time in cornering mode, 10% of the time in road mode ( Long range). These three driving situations correspond to lighting modes that represent 30% of the life of the lamp. These driving situations require intense lighting. The lamp will be powered at the maximum voltage for these modes of lighting. Consider a voltage provided by the battery of 13.2 volts. The life of such a lamp powered with this voltage is about 250 hours. The service life consumed by all these three driving situations is therefore 30% * 250h = 75 hours. Taking into account a B3 of the H9 lamp of 250 hours, so there remains 250h-75h = 175 hours during which the lamp H9 can be powered at voltages lower than the battery output voltage, so as to reduce consumption while providing less powerful lighting performance but nevertheless acceptable for other driving situations. This significantly increases the service life. To achieve a lifetime of about 900 hours, ie equivalent to that of a lamp type H7LL (H7 lamp with extended life, Long Life), it reduces the power supply voltages depending speed ranges for example: - Speed> 30km / h (65% of the remaining time not included in the 30% of use at 13.2V) performances equivalent to those of an H7LL: V = 11.8V (voltage for which lamp life is multiplied by 4) - Speed <30km / h or Speed = 0km / h (35% of the remaining time not included in the 30% of use at 13,2V): reduced but regulatory performance: V = 10.5V, (voltage for which the lifetime of the lamps is multiplied by 19) We thus arrive, for this driving profile, to a total lifetime of the lamp of: Ltime = 75h13,2vo, ts + 175 x 0.65 x 4 + 175 x 0.35 x 19 = 1693 hours In this case, based on a history of the applied voltages and durations of the lighting modes, the calculator can evaluate Anticipating this excessive life, for example by raising the voltage of the projectors from 10.5V to 11V to reach 612h lifetime in the city, a total of 1142h estimated lifetime for the lamp.

Thus, the computer, according to this history, adjust the voltage so that, for example, if the lifetime is greater than the threshold of acceptable life, can be increased the applied voltage. If it is lower, the voltage can be decreased to extend the service life. The invention thus makes it possible to multiply the lifetime of the lamp by 6.68 while at the same time providing lighting conditions adapted to driving situations. Nevertheless, we can choose to raise the voltage of the projectors from 10.5V to 11V to arrive at 612h lifetime in the city is a total of 1522h. The low-speed lighting will therefore be greater than the regulatory lighting and the lifetime of the lamps will still be multiplied by 6.1 compared to a maximum permanent power use. If, as explained above, the driver does not follow the predetermined driving profile defined by the manufacturer, the lighting computer automatically modifies the voltages so as to still achieve the expected life with this real driving profile.

For example, if the calculator detects that the relative duration of use at full power is 60% (road function and high speed and / or cornering for example), then the controller adjusts the voltages of each of the driving modes of so to exceed the 1000 hours of life with the actual profile of the driver. This example is easily transposable and makes it possible to highlight the advantages of the invention: to maintain an acceptable lifetime (typically of the order of 1000h), while offering high performance under the conditions that require it (function of advanced lighting, cornering lighting orientation function generally referred to as its DBL - English Dynamic Bending Light), "normal" performance under standard driving conditions and regulatory performance under conditions that require nothing other (city code, stationary code, etc.) A road regulation defines a point grid on a vertical screen located at a given distance from the projector. For each of these points, the regulation will define acceptable light intensities. For example according to European regulations, for projectors approved in "code", the regulation authorizes 121x. However, it is common to have an illumination of 25 lx to 25m in point 75R .. This allows to lower the voltage across the lamps at a voltage below 12V. In the case of an illumination of the 75R point controlled at 151x obtained by under-voltage of the lamp, and insofar as the other points defined in the standard remain above the regulatory limits, the application of the formula expressing the luminous performance of the lamp in power -3,25 of the voltage, allows to consider an applied voltage of -10,25V: i is xLn V = 1 2 xe 3,25 25 V = 10,25V In running conditions at reduced speed (city, traffic jam, traffic lights, ..) we can consider reducing the power of (10.37 / 14) * 2 or 35W per lamp, that is to say 70W per vehicle . This reduction in power leads to a considerable reduction of CO2 emissions (approximately 3.5 gr CO2 / km in this case). However, it is accepted that the cycle of recombination of the halogen in a lamp is not affected until the voltage is not less than 10V. This application is thus made perfectly possible in practice.

As a vehicle drives more than two-thirds of its time in the city, this drop in power can significantly increase its life. In case, for use of a bi-halogen type H9 lamp, the lifetime gain thus obtained is used to increase the lighting performance in turns (function generally designated by its acronym Dynamic Bending Light) ), in road mode, or even in highway mode to increase the performance by 30%. In this configuration, the projector can be raised using static or dynamic correction motors. For this purpose the motors can be DC motors or stepper motors. The invention is not limited to the embodiments described but extends to any embodiment within its spirit.

For example, the manufacturer may decide to reduce the voltage across the lamps only to reduce emissions of 002 in the city. Furthermore, according to one embodiment, it is expected to equip the projector with the same lamp for the code and route functions. According to another embodiment, the projector comprises several lamps. Alternatively, one or more of these lamps provide both the code and route functions. According to another variant, at least one of these lamps is dedicated to only one of the functions route or code.

Claims (20)

CLAIMS1- A method for controlling the power supply of a vehicle headlamp (10) capable of providing road-based and / or code-based illumination, characterized in that it comprises the following steps for at least one of the code and route functions: - at least one driving parameter relevant for vehicle lighting is determined, - a plurality of lighting modes characterized by the value of this at least one parameter are defined, - each mode is assigned lighting a power mode of the projector, - it stores in a memory the power mode associated with each of the lighting modes. 2- Method according to the preceding claim, wherein each projector power mode corresponds to a given voltage applied to the projector (10) and / or corresponds to a given intensity applied to the projector (10). The method according to any of the preceding claims, wherein the projector comprises a plurality of light sources (S1, S2, S3, S4) and wherein each projector power mode defines the activation or deactivation of the projector. at least one light source (S1, S2, S3, S4) independently of the other light sources (S1, S2, S3, S4). 4- Method according to the preceding claim, wherein the illumination provided by the projector generates a light pattern (61, 62, 63, 64, 71, 72) and a light intensity and wherein the power modes are defined so the pattern (71, 72) is substantially identical for at least a plurality of power modes and so that for this plurality of power modes the light intensity varies from a power mode to the other. 5. Method according to the preceding claim, wherein the light sources (S1, S2, S3, S4) are incandescent lamps, light-emitting diodes or modules comprising a plurality of light-emitting diodes or a plurality of lamps. The method as claimed in any one of the preceding claims, wherein said at least one parameter comprises at least one parameter internal to the vehicle chosen from the following parameters: a vehicle speed, navigation data, a vehicle engine speed, the speed of rotation of a vehicle steering wheel, activation of windscreen wipers and fog lamps, acceleration value, speed or angle of application of a brake or acceleration pedal, activation of a driver command. 7. A method according to any one of the preceding claims, wherein said at least one parameter comprises a parameter that reflects the external state to the vehicle selected from the following parameters: ambient brightness, the brightness of a public lighting, the brightness of 'natural lighting, the degree of pollution, the number of vehicles within a given perimeter, the distance to a vehicle tracked, the relative speed and / or acceleration with respect to a tracked vehicle, a follower vehicle or a vehicle crossed, the color of a marking line on the ground, the meaning of a sign, the presence of an obstacle, the arrival at a crossroad or roundabout, the presence of an urban environment, the presence of a street light, the presence of a red light, the presence of fog, rain, snow or smoke, the detection of an obstacle. The method according to any one of the preceding claims, wherein said at least one parameter comprises a parameter that translates a traffic density, the traffic density being determined by navigation data reflecting the traffic density or the speed of the traffic. vehicle combined with at least one sub-parameter taken from: the distance from a tracked vehicle, the number of vehicles within a given perimeter, navigation data reflecting the traffic density. 9- Method according to any one of the preceding claims, wherein during use of the vehicle: - values relative to said parameter are received, - one of the plurality of lighting modes is identified, the lighting mode corresponding to these values, - a power mode of the projector is determined according to said lighting mode. 10- Method according to the preceding claim, wherein the values relating to said parameter are derived from one or more sensors selected from the following sensors: a camera, a lidar, a radar (45). 11- Method according to any one of the preceding claims wherein the power supply modes are defined by performing the following steps: - one defines a desired lifetime for the projector and / or a desired maximum energy consumption of the projector for a duration projector operating data, - a predetermined driving profile characterized by a relative duration of use of the projector in each of the lighting modes is defined, - a power mode is calculated for each lighting mode so as to With this mode of supply, the projector provides satisfactory illumination for this lighting mode while having a service life close to the desired lifetime and / or while inducing an energy consumption close to the maximum energy consumption. desired for use corresponding to the predetermined driving profile. 12- Power control device for a vehicle headlamp (10) capable of providing road-based and code-based illumination, characterized in that for at least one of the code and route functions, it is arranged to: - receive values relating to at least one relevant parameter for the lighting of the vehicle, - identify, among a plurality of lighting modes, a lighting mode corresponding to these values, - determine a mode of the projector according to the lighting mode identified. 13- Device according to the preceding claim comprising at least one of the following means configured to receive the at least one relevant parameter for lighting the vehicle: - means for detecting the number of vehicles in the vicinity of said vehicle, - means for detecting the distance between said vehicle and at least one vehicle followed, means for detecting the absolute speed of said vehicle, means for detecting the relative speed and / or acceleration of said vehicle with respect to the vehicle followed by a follower vehicle or a crossed vehicle; means for detecting the color of a marking line on the ground; means for detecting the meaning of a traffic sign; detection means; and measuring the ambient brightness, - means for detecting the presence of an urban environment, - means for detecting the presence of lampposts, - detection means for the presence of obstacle, means for detecting the ignition of brake lights of a vehicle followed. 14- Device according to the preceding claim wherein said means comprises a camera arranged to receive the at least one relevant parameter for the illumination of the vehicle. 15- Device according to claim 12 comprising a radar or a lidar configured to receive the at least one relevant parameter for lighting the vehicle, the parameter being taken from the following parameters: - the number of vehicles in the vicinity of said vehicle, - the detection of a vehicle followed, - the distance between said vehicle and a vehicle followed, - the relative speed and / or acceleration with respect to the vehicle followed, a follower vehicle or a crossed vehicle, - the presence of an obstacle. 16- Device according to any one of the two preceding claims wherein said means comprises a vehicle location system and a traffic data reception system issued by a remote traffic observation center. 25 17- lighting projector (10) for vehicle comprising a device according to any one of claims 12 to 16. 18- A projector according to the preceding claim comprising a plurality of light sources (Si, S2, S3, S4) and wherein the device is arranged to control, depending on the identified lighting mode, the activation and the deactivating at least one of the plurality of light sources (S1, S2, S3, S4) and independently of the activation and deactivation of the other light sources (S1, S2, S3, S4) . 19- A projector according to the preceding claim wherein the device and the distribution of the light sources (S1, S2, S3, S4) are configured so that, for at least a plurality of lighting modes, the light intensity generated the projector varies and the shape of the light pattern (71, 72) generated by the projector remains substantially constant from one lighting mode to another. 20- projector according to the preceding claim wherein the light sources (Si, S2, S3, S4) are individual light emitting diodes or modules comprising a plurality of light emitting diodes.