WO2018024505A1 - Lamp module having at least one semiconductor light source - Google Patents

Abstract

The invention relates to a lamp module for a vehicle, having at least one semiconductor source, an operating device for operating the at least one semiconductor light source which is designed to operate the at least one semiconductor light source by means of a first pulsed current, wherein the operating device is designed to modify the absolute current level in a pulse of the first pulsed current and the arithmetic mean of the first pulsed current independently of each other.

Description

 Light module with at least one semiconductor light source.

description

TECHNICAL FIELD The invention relates to a vehicle lighting module having at least one semiconductor light source and an operating device, which is set up to operate the semiconductor light sources with a pulsed current.

BACKGROUND The invention is based on a vehicle lighting module having at least one semiconductor light source according to the preamble of the main claim.

There are vehicle light modules, e.g. known for the equipment of a vehicle headlight. These known lighting modules usually have a plurality of white semiconductor light sources. White semiconductor light sources are typically blue or ultraviolet emitting LEDs having a conversion layer that converts the blue or ultraviolet light to longer wavelength light. The converted light, together with a proportion of the light emitted by the LED and not converted, gives a light with a white color impression. Since the LEDs are always operated at rated current, the result is a stable white point within the ECE R48 control.

The disadvantage, however, is that depending on the time of day and weather in which the vehicle is, different light colors would be optimal. In rain, snow and fog, for example, a light color with a lower color temperature would provide better visibility, while in sunshine, a higher color temperature will provide better visibility in daytime running light. In addition, it would be advantageous to adapt the light color or the emission spectrum of the at least one semiconductor light source with regard to the increasing degradation and shift of the blue-yellow sensitivity of the eye with the age of a driver. task

It is an object of the invention to provide a vehicle light module, which no longer has the disadvantages mentioned above. Presentation of the invention

The object is achieved with a lighting module for a vehicle, comprising at least one semiconductor light source, an operating device for operating the at least one semiconductor light source which is set up to operate the at least one semiconductor light source with a first pulsed current, wherein the operating device is set up, the absolute current level in a clock of the first clocked current and the arithmetic mean of the first clocked current to change independently.

The vehicle may be, for example, a motor vehicle (eg, a car such as a passenger car, truck, bus, etc. or a motorcycle), a railroad, a watercraft (eg, a boat or a ship) or an aircraft (eg, an airplane or a helicopter ) be.

The absolute current level in a clock is here considered to be the peak value in a first half-cycle or the minimum value of the current in a second half-cycle during one cycle (one full wave) of the current. For a square operation, this value would be e.g. the absolute value of the current in a rectangular half-wave.

The arithmetic mean value of the clocked current is the arithmetic mean value over the time of the clocked current, ie over several full waves. The arithmetic mean, e.g. of a PWM signal with the duty cycle 0.5 is 50% of the absolute current level of this pulsed current.

In a particularly preferred embodiment, an optically downstream conversion element in the light emission direction of the at least one semiconductor light source is provided for partially converting the light emitted by the at least one semiconductor light source into light of other wavelengths, see above that together with the emitted light of the semiconductor light source produces white light, which fulfills the requirements of the ECE Norm R48.

The conversion element produces so-called conversion light-emitting diodes, which are able to emit white light, which is only insufficiently possible for a pure semiconductor light-emitting diode.

In a preferred embodiment, the operating device is set up to operate the at least one semiconductor light source in a first half-wave with a first current value which is greater than zero, wherein a first color locus within the ECE white field is obtained for the light emitted in the first half-wave. rule R48 is set, wherein the operating device is set up to operate the at least one semiconductor light source in a second half-wave with a second current value which is greater than zero, wherein for the light emitted in the second half-wave, a second color locus within the ECE White field according to the rule R48, wherein the first and the second color coordinates differ from each other.

With this measure, the color locus of the emitted light can be adjusted very accurately by the corresponding energization of the respective half-waves.

In a further preferred embodiment, the lighting module has a plurality of semiconductor light sources which are operated with the first clocked current. By means of a plurality of semiconductor light sources, the light output can advantageously be increased and the light can be better directed.

In another embodiment, the light module comprises a plurality of semiconductor light sources, which are combined into at least two groups, wherein the operating device is set up to operate the first group of semiconductor light sources with the first clocked current, and to operate the second group of semiconductor light sources with a second clocked current ,

With this measure, the color location of the entire radiated light can be controlled even more accurately and in addition can be achieved on the installation position of the groups of semiconductor light sources special effects. In the following, general is also referred to as pulsed current, here the first or second pulsed current or else another pulsed current may be meant.

The clock frequencies of the half-waves of the first clocked current and / or the clock frequencies of the half-cycles of the second clocked current can be in the Hz to MHz range and individually adapted to the different requirements.

Instead of a phosphor-converted LED, it is also possible to use a laser whose primary radiation is directed onto a wavelength conversion element and is at least partially converted by it into a conversion light. For example, the laser may be a blue laser diode and the wavelength conversion element may be a cerium doped phosphor which at least partially converts the blue primary light to yellow conversion light. Unconverted blue primary light and yellow conversion light together produce white mixed light, which can also be referred to as useful light. Such an irradiation and conversion arrangement is also referred to as a laser-activated remote phosphor arrangement (LARP). LARP light sources can also be combined in one application with phosphor converted as well as with non phosphor converted LED light sources. The embodiments described below are to be read analogously to the light sources described above and their combinations.

The lighting device according to the invention makes it possible to adapt LED light sources, which are used in each one of the two headlight assemblies of a vehicle, at least within a Binningklasse in their light color, that a possibly occurring color difference of the two headlights, with an equal light function, are substantially compensated can. As a result, it is possible to use larger binning classes for the LEDs, since color matching is also possible in them. The use of larger binning classes reduces the costs with regard to the necessary color presorting of the LEDs.

The clock frequencies of the half-waves of the first clocked current and / or the clock frequencies of the half-waves of the second clocked current can also be related to the layer thicknesses of the conversion substance of the conversion element be adjusted. The conversion substance used is usually a phosphor specially adapted to the wavelength emitted by the semiconductor light source. Since not all radiation but only a part is normally converted, and the resulting mixed light determines the white point, the layer thickness of the conversion substance of the conversion element also enters the resulting white point. In the case of uneven layer thicknesses and concomitant fluctuations in the emitted light color, the light color can be adjusted by adjusting the clock frequencies of the half-waves of the first clocked current and / or the clock frequencies of the half-waves of the second clocked current so that they are as equal as possible via the various semiconductor light sources. In this case, the clocked current is preferably a pulse-modulated current. This has an advantageous effect on the color emission behavior of the semiconductor light sources.

Particularly preferably, the pulsed current is a pulse width modulated current. On the one hand, this measure can further positively influence the radiation behavior of the semiconductor light sources, and the operating device can be constructed in a particularly simple and cost-effective manner.

In a further embodiment, the operating device is set up to set the ratio of the absolute current level to the value of the arithmetic mean value of the pulsed current by means of the duty cycle of the pulse width modulation. This ensures a particularly simple and cost-effective embodiment, which nevertheless has full functionality.

The operating device is set up in a further preferred embodiment to provide multiple light functions for a vehicle. By providing multiple lighting functions centrally, additional effects can be achieved and the cost of these lighting functions further reduced.

In this case, the operating device is set up to accomplish various light functions of the vehicle with different absolute current levels of the pulsed current. With this measure, one can achieve a different color location for each light function, which has a positive effect on the distinguishability of the light functions of the vehicle. _

In a further embodiment, the absolute current levels of the pulsed current are adapted to the situation in at least one light function. This can increase the safety of the vehicle guidance in a previously unknown manner and allow very useful additional functions. Depending on the situation means in the following, that due to a certain situation in which the vehicle is the absolute current levels of the pulsed current and thus the white point of the radiated light is changed. A situation condition may e.g. be the speed of the vehicle. The outside temperature or the current precipitation such as rain or snow can also be a situation condition.

For example, the absolute current levels of the pulsed current may be adjusted based on a current speed of the vehicle to immediately recognize the approximate driving speed while driving without having to look at the speedometer. However, the absolute current levels of the pulsed current can also be adjusted due to the weather conditions in which the vehicle is located. This can contribute to safety by immediately recognizing, for example, based on the light color of the emitted headlight, that the road is very cold and thus possibly iced. However, the absolute current levels of the pulsed current can also be adjusted on the basis of the current temperature of the semiconductor light sources. This would indicate overload and overheating of the semiconductor light sources.

In another embodiment, the absolute current levels of the pulsed current can be adjusted as a function of the cumulative lighting duration of the at least one semiconductor light source. This could be seen by the light color, when the semiconductor light sources are expected to have reached their end of life and when to expect a failure of the same. Further advantageous developments and refinements of the lighting module according to the invention for a vehicle emerge from further dependent claims and from the following description.

Preferred embodiments are to be found in the dependent claims and the entire disclosure, wherein in the presentation is not always distinguished in detail between device and use aspects; In any case, implicitly, the disclosure must be read with regard to all categories of claims.

BRIEF DESCRIPTION OF THE DRAWINGS Further advantages, features and details of the invention will become apparent from the following description of embodiments and from the drawings in which identical or functionally identical elements are provided with identical reference numerals. Showing:

1 shows the current profile of a direct current, in which the absolute value of the

 Current and the arithmetic mean of the current are equal,

Fig. 2a, b is the current waveform of a rectangular current in which the absolute value of the current and the arithmetic mean of the current are different, and the duty cycle is changed, Fig. 3a, b, the current waveform of a rectangular current, in which the absolute value of the current and the arithmetic mean of the current are different, and the absolute value is changed,

4a, b the current profile of a rectangular current in which the absolute value of the current and the arithmetic mean of the current are different, and the duty cycle and the absolute value is changed,

5 shows the current profile of a rectangular current in which the absolute value of the current and the arithmetic mean value of the current are different, the current waveform is freely composed of different currents and half-wavelengths,

6 shows a very simple current form with different current intensities,

Fig. 7 shows a detail of a CIE standard color diagram with registered

 Planck or Black Body curve and ECE R48 limits

Control, wherein four different white points are given for four different absolute current values of a semiconductor layer with a conversion layer,

Fig. 8 is a detail of a CIE standard color diagram with registered

 Planck or Black Body curve and ECE R48 limits

Scheme, whereby the standard binning classes for headlamps are indicated,

9 shows the functions of the X (Cx) and Y (Cy) coordinates over the operating current of the semiconductor light source, FIG. 10 shows the function of the light intensity over the operating current of the semiconductor light source,

Fig. 1 1, a light emitting module in a first embodiment with two groups of

 FIG. 12 shows a light-emitting module of a second embodiment with four groups of semiconductor light sources which can be controlled independently of one another

 Semiconductor light sources that can be driven independently of each other,

13 shows a lighting module of a third embodiment with four groups of

 Semiconductor light sources that can be controlled independently of each other.

Preferred embodiment of the invention "

The core of the invention is the utilization of an effect that occurs in many LEDs with conversion layer and can be used preferably in some high-performance light emitting diodes. For many applications LEDs with a conversion layer are used today. These LEDs are also commonly known as white LEDs, as for example in DE202014001376, DE102012223854,

DE102014292863, DE102015218021 described. The white light is generated by the fact that the LED itself emits light with a wavelength in the blue to ultraviolet range, and then the conversion layer converts this short-wave light partly into light with longer wavelengths. Part of the blue light passes through the conversion layer so that all of the emitted light appears white and is located on a CIE standard color chart near the Planck curve, also called the black body curve. This point is called white point below. The operating principle is e.g. on Wikipedia

(https://de.wikipedia.Org/wiki/Leuchtdiode#Lumineszenz) explained. Whenever LEDs or light-emitting diodes are mentioned below, they always mean white LEDs with a conversion layer as described above. If the LEDs are operated with a pulsed current, wherein the current level is variable in one cycle, then the white point can be adjusted within certain limits. The current level in one cycle is the absolute current level in this cycle, ie the largest current briefly applied to the LED. The light intensity of the LED is u.a. depending on the average current flowing through the LED. Here the arithmetic mean of the current is proportional to the intensity of light. Thus, the light color can be set via the largest, absolutely flowing current, while the average current intensity can be used to adjust the light intensity.

In the case of direct current, the absolute value of the current and the arithmetic mean of the current are the same. Here, the largest current applied to the LED corresponds to the average current flowing through the LED. The current is 1A in both cases. Fig. 2a shows the current waveform 210 of a rectangular pulsed current in which the absolute value 214 of the current and the arithmetic mean 212 of the current are different. The signal is a kind of PWM signal in which in one half-wave a higher current 214 (the higher absolute value 214 of the current, also called HIGH pulse below) and in the other half-wave in lower current 216 (the lower absolute value 216 of the current, hereinafter also called LOW pulse) flows. The higher absolute value 214 of the current in the one half-wave here is 2A, the lower absolute value of the current in the other half-wave 216 is 1A. The arithmetic mean at the 50% duty cycle shown here is (1 A + 2A) / 2 = 1, 5A. The light intensity of the LED is therefore essentially dependent on the arithmetic mean (= 1, 5A), while the time-integral white point of the LED from the time value of the higher absolute value (= 2A) of the current 214 and the temporal sum value of the current of the lower absolute value of the current 216th depends. 2b, the pulse width ratio of the square-wave clocked current 220 is changed while the absolute value of the current 224 remains constant, and thus also the time components and thus the temporal sum values of the wavelengths of the respective radiated light. The mean value of the current 222 thus results from the time component of the higher absolute value 224 and the time component of the lower absolute value 226. In the case of a pure change in the clock ratio, the arithmetic mean value 222 of the current also changes, in which case it increases. As a result, when the operating mode according to FIG. 2a is changed to that shown in FIG. 2b, the radiated light intensity also increases and the white point also changes. In this method, therefore, the radiated light intensity and the emitted wavelengths are changed. As a result, depending on the operating method, two different white points can be set, which then leads to a changed color impression in the temporal superimposition of the white points according to the respective clock ratios, in contrast to the white point of a light-emitting diode operated at a constant current value corresponding to the arithmetic mean value. It should be noted that the two lower absolute values 216 and 226 of the operating currents are not equal to zero, so that the LEDs operated therewith do not equal zero should emit light at any time. This statement also applies to subsequent FIGS. 3 to 5.

The current profile in FIG. 3 a is similar to that in FIG. 2. It is likewise a type of pulse width modulation with two different current levels 314, 316 in the pulse half-waves of the current form 310. This has an arithmetic mean value 312. In Fig. 3b, the pulse height is now modified, but the pulse times left the same. The high-pulse is increased by the same current value as the

LOW pulse is lowered. As a result, the arithmetic mean 322 does not change from the arithmetic mean 312 of the current waveform in FIG. 3a. However, the absolute values 320, 326 of the current levels of the current form change, resulting in different wavelengths in the radiated light of an LED operated therewith. With this measure, the color spread of the emitted light of an LED is even greater. However, the arithmetic mean value of the current remains unchanged, so that the intensity of the radiated light remains unchanged. As in the case of the transition from the operating mode of FIG. 2 a to that of FIG. 2 b, a change in the (integral) color impression takes place here as well during the transition of the operating mode from FIG. 3 a to FIG. 3 b due to the respective time components of the two white points. The two white points are within the white field described above according to the ECE R48 regulation. Depending on the mode of operation and the absolute current level in the half-waves, the white points may also lie in other areas of the CIE standard color diagram.

4, the absolute current level of the lower current values 216, 426 is changed and, at the same time as in FIG. 2, the duty cycle is also changed. The duration of the HIGH pulse 414, 424 is longer in FIG. 4b, that of the LOW pulse 416, 426 is shorter. As a result, the arithmetic mean of the current is higher, and the radiated light intensity is also higher. The lower absolute value of the current level 426, which is lowered in comparison to FIG. 4a, leads to a further spreading of the two white dots according to the difference of the current values 424, 426 and thus to a change in the integral color impression. Thus, as in the previous Figures gone changed figures, the wavelengths of the emitted light and thus the light color by the described operating scheme of the LEDs.

Fig. 5 again shows a free current waveform with varying pulse heights and mean current values. Here are the always rectangular current heights of the different pulses freely joined together. Thus, with appropriate knowledge of the current-dependent wavelength shifts of the different wavelengths, firstly, as in the above-described methods, a corresponding respective color locus (white point) can be set. The temporal sum value of all respective white points results in an adjustable sum color location for the human eye or a sensor and thus an adjustable color impression. Furthermore, however, the color reproduction can also be improved only by the embodiment described by way of example in FIG. 5, likewise due to the wavelength spectrum changed with a corresponding current shape.

Fig. 6 shows a very simple current form. The current is simply increased or decreased within the allowable current limits of the LEDs used. Depending on the height of the current form results in a corresponding white point. The height of the current form also determines the light intensity of the emitted light. With this simple current form, the white point can not be decoupled from the light intensity.

7 shows a section of a CIE standard color diagram with registered Planck or Black-Body curve and the limit values 31 of the ECE regulation R48, wherein four different white points 33, 34, 35, 36 are indicated for four different absolute current values of the semiconductor light source. The CIE standard color chart is a diagram illustrating a light color of a light emitted from a light source. An explanation may e.g. on Wikipedia

(httpsi // de.wikipedia.org / wiki / ClE-Normvalenzsvstem) are retrieved. The ECE R48 regulation contains requirements for light sources on vehicles which are in take part in the traffic. For headlamps, for example, area 31 in the CIE diagram is prescribed for the radiated light. This area is oriented roughly along the Planck curve 32 and leaves in a certain range around the

Planck curve 32 around different light colors. Depending on the absolute value of the current flowing through the LED, the white point of the light emitted by the LED shifts.

The four different illustrated white points 33, 34, 35 and 36 correspond to four different absolute values of the current flowing through the LED:

White point 33: 200mA white point 34: 500mA

White point 35: 1000mA

White point 36: 1500mA

Depending on the current level, therefore, a shift of the color location of the light can be achieved and thus a different impression of the radiated light for the human eye. In the case of a change in the current intensity as described in FIGS. 2 to 5, different color locations are thus set in the respective cycle times and thus in the temporal sum value a resulting integral color impression for the human eye or a sensor, for example a camera CCD chip.

8 shows a section of a CIE standard color diagram with a registered Planck or Black Body curve and the limit values 31 of the ECE regulation R48. In addition, the various standard automotive binning classes for white LEDs 81 to 87 are also entered here. It is good to see that even within the binning classes, the color location of the individual LEDs need not be uniform but can move within the illustrated quadrant of the respective class 81 to 87. With the method according to the invention, it is now possible to adapt the color location, for example in the case of a headlight, such that at least some LEDs of the same binning class or of a neighboring binning class transmit the light with essentially the same color. radiate the same color, so that the appearance of eg a vehicle is more uniform towards the outside.

Fig. 9 shows the functions of the X (Cx) and Y (Cy) coordinates of the white point on the CIE standard color chart over the operating current of the LED. It is good to see that the coordinates have a very strong dependence on the absolute value of the operating current. The curves over the operating current run non-linearly. As the current through the LED increases, the Cx and Cy coordinate values decrease to smaller values, causing a shift toward the blue or higher light color. When using other phosphor compositions, the curves may be different from those shown in FIG. 9. Thus, by selecting suitable phosphors, the curve shape can be adjusted or adapted to the requirements to be met. This also makes it possible to set additional color loci within the CIE color triangle.

Fig. 10 shows the function 1 1 of the light intensity over the average operating current of the LED. This is approximately linear, with higher currents the efficiency of the LED drops slightly due to the higher operating temperatures and thus the reduced conversion efficiency of the phosphor. When rated current of the LED has the

Light intensity is a value of 1.

The color temperature of the emitted light can now be decoupled from the intensity of the emitted light when the LED is supplied with a pulsed current, e.g. is operated with a pulse width modulation (PWM). In this case, in the current-flowing half-wave of the absolute value of the current and thus the white point of the emitted light can be adjusted, while on the duty cycle of the average current and thus the intensity of the emitted light can be adjusted.

This effect is now used to positively enhance various light functions in vehicles. For example, in an LED headlamp when switching between low beam and high beam, the light color of the headlight can also be switched to realize, for example, the high beam color temperature higher than the dipped beam. The setting of the light color can also be dependent on the speed, for example, a higher light color can be set with increasing speed of the vehicle. The light color can then be at a speed of 50km / h about 4000K and with increasing speed also rise to be at 200km / h about 6500K. Furthermore, the light color can also be dependent on the current weather in which the vehicle is located. For this purpose, for example, a rain sensor of an automobile can be used, and when it rains, the light color can be changed to lower color temperatures, as this gives a better view.

The color temperature of the emitted light can also be dependent on the outside temperature. It is also conceivable the color temperature depending on the temperature of the LEDs. In general, the color temperature of the radiated light can be dependent on environmental influences such as rain, snow, fog, day, night or dusk, in order to achieve positive effects on the driver and to increase road safety. It is also possible, by the method of the adjustable light colors described above or the resulting integral color impression, to at least partially adapt the light color to the age-changed spectral eye sensitivity of the vehicle driver and / or passengers, for example by adjusting the blue component in accordance with the Age is increased. Here, the person in question can set an age or by means of a

Biofeedback method (eg eye measurement by on-board camera) provide the vehicle. This method can thus be applied in particular for the age-related changes in twilight and night sensitivity of the human eye sensors (rods, cones), whereby the driving safety is increased. In one embodiment, a plurality of LEDs are arranged on a module and are all controlled jointly by a PWM signal, so that all the LEDs are set to the same respective white point. The LEDs can be connected in series or in parallel. But it can also occur a hybrid form of series and parallel connection.

In another embodiment, the LEDs arranged on the module are divided into one or more groups. These groups can be individually controlled by the operating device with different current / duty ratios and thus in each case shine in different, resulting from the respective current strengths, light colors.

Fig. 1 1 shows a lighting module 1 in a first embodiment with two groups of LEDs 5, which can be controlled independently. The LEDs 5 are arranged in a circular surface on this module. In this case, the LEDs are arranged in a group of inner LEDs 51 and a group of outer LEDs 52. These can be controlled differently, so that e.g. the group of external LEDs 52 are operated at a higher color temperature than the group of internal LEDs 51, or vice versa.

Fig. 12 shows a lighting module of a second embodiment with five groups of LEDs, which can be controlled independently. Here, there are four outer groups 531, 532, 533 and 534, which are arranged outside in the circumferential direction on the circular surface of the LED module 1. An inner group 535 includes the inner LEDs 5 that do not belong to any of the outer groups. Here, too, the operating device is set up to control the groups independently of one another and to achieve different light colors with the same luminous intensity via the ratios of absolute current height and duty cycle. In this case, for example, the outer groups can also be operated offset in time with different light colors, resulting in a changing light effect over time. This can be a kind of running light, for example in the Clockwise or counterclockwise or clockwise, or even a flashing operation, for example, all four outer groups simultaneously, or even mutually, so that two opposite outer groups are controlled together with a different clock ratio than the two other outdoor groups, or that two adjacent outdoor groups are controlled differently than the other two outside groups. It should be noted that the LEDs are not switched off, but only switched in the light color. It is also possible to control the inner group and some or all outer groups counter clocked with the same clock modulation, that is, that the respective pulse shapes of the two counter-clocked groups are mirrored around the respective average current value, so that, for example, when the outer LED groups a

HIGH current value obtained, the inner group receives a LOW current value and vice versa. So here is a variety of variations possible, all cause a temporally and / or locally changed color impression.

Fig. 13 shows a lighting module of a third embodiment with four groups of LEDs which can be controlled independently. Here, the LEDs 5 are arranged square and the groups are arranged in four bars 541, 542, 543, 544, which together again form the square. If here too the groups are operated in a time-sequential order, that is to say first the group 541, then the group 542 and so on, with different light colors, then wiping or blinking effects can be achieved. The groups can be aligned horizontally (rows) or vertically (columns). It is also possible to define groups in which LEDs of different rows and columns are combined to form a new group. The group division can be constant in time or, for example, change according to constant, freely defined or random time intervals, for example by means of a dedicated operating program. As already mentioned above, this effect can be used to positively enhance various light functions in vehicles or in different driving conditions (speed, weather, visibility, etc.) are used. In general, this operating method for adjusting the color impression can also be applied to other light sources, such as organic light-emitting diodes OLED, to laser-activated remote phosphor LARP light sources and to non-phosphorus converted light emitting diodes LED, as well as to a combination of these light sources.

Also, the adjustable with the respective pulse or clock ratios white points must not only lie within the ECE white field according to the scheme R48, but may also be in other areas of the color triangle. Thus, this method is also used for applications e.g. from the fields of architectural lighting, effect lighting, underwater lighting, signal lights, ship lights, and studio lighting, applicable.

Also, the durations of the clock rates, ie the time length of the respective HIGH and LOW current values, can be adapted to the integration behavior of the human eye and / or a photo sensor and / or a camera chip. These time intervals can be in the range of microseconds, milliseconds or seconds.

This method can also be applied in a modified form to pulse or clock sequences in which the LOW current value is lowered to zero. The concomitant lowering of the light level can be used, for example, when a headlight is to be slowly faded in or out when the light color is changed or specially set.

" _N

 19

LIST OF REFERENCE NUMBERS

1 light module

 5 LEDs, LEDs

 51 group of internal LEDs

 52 Group of external LEDs

 531 - 534 Group of external LEDs

 535 group of internal LEDs

541 - ^■ 544 Bar-shaped group of LEDs

 1 1 Function of the light intensity via the average operating current of the LED

31 ECE Regulation R48 limit curve in the CIE standard color diagram

32 Black-Body or Planck curve in CIE standard color chart

 33-36 white points in the CIE standard color chart

 81 -87 Standard Automotive Binning classes for headlights

 1 10 DC

 210, 220 current waveform of the pulsed current

 212, 222 arithmetic mean of the clocked current

 214, 224 upper absolute value of the pulsed current

 216, 226 lower absolute value of the clocked current

 310, 320 Current waveform of the pulsed current

 312, 322 arithmetic mean of the clocked current

 314, 324 upper absolute value of the pulsed current

 316, 326 lower absolute value of the clocked current

 410, 420 current waveform of the pulsed current

 412, 422 Arithmetic mean of the clocked current

 414, 424 upper absolute value of the pulsed current

 416, 426 lower absolute value of the clocked current

 510 Current waveform of the pulsed current

 512, 522 Arithmetic mean of a period of the clocked current

610 DC different height

Claims

claims

1 . Light module for a vehicle, comprising:

 At least one semiconductor light source,

 an operating device for operating the at least one semiconductor light source which is set up to operate the at least one semiconductor light source with a first clocked current,

 wherein the operating device is set up to independently change the absolute current level in one cycle of the first clocked current and the arithmetic mean value of the first clocked current, wherein a conversion element optically connected in the light emission direction of the at least one semiconductor light source for partially converting the radiated from the at least one semiconductor light source Light is provided in light of different wavelengths, so that together with the emitted light of the semiconductor light source produces white light, which meets the requirements of ECE R48 standard,

 wherein the operating device is set up to operate the at least one semiconductor light source in a first half-wave with a first current value which is greater than zero, wherein a first color locus within the ECE white field according to the first half-wave is emitted for the light emitted in the first half-wave

Rule R48 stops,

 wherein the operating device is set up to operate the at least one semiconductor light source in a second half-wave with a second current value which is greater than zero, wherein a second color locus within the ECE white field sets in accordance with rule R48 for the light emitted in the second half-wave .

 characterized in that the first and the second color coordinates differ from one another.

2. Light module according to claim 1, characterized in that it comprises a plurality of semiconductor light sources which operate with the first clocked current. ben.

3. Light module according to one of claims 1 or 2, characterized in that it comprises a plurality of semiconductor light sources, which are combined into at least two groups, wherein the operating device is adapted to operate the first group of semiconductor light sources with the first clocked current, and the second group of semiconductor light sources with a second clocked current to operate.

4. Light module according to one of claims 1 to 3, characterized in that the pulsed current is a pulse-modulated current.

5. Light module according to claim 4, characterized in that the pulsed current is a pulse width modulated current.

6. Light module according to claim 5, characterized in that the operating device is set up to set the ratio of the absolute current level to the value of the arithmetic mean value of the pulsed current by means of the pulse duty factor of the pulse width modulation.

7. Lighting module according to one of the preceding claims, characterized in that it is adapted to provide a plurality of lighting functions for a vehicle.

8. lighting module according to claim 7, characterized in that it is arranged to accomplish various lighting functions of the vehicle with different absolute current levels of the pulsed current.

Luminous module according to claim 8, characterized in that m at least one light function, the absolute current levels of the clocked current can be adjusted depending on the situation.

10. Light module according to claim 9, characterized in that the absolute current levels of the pulsed current are adjusted due to a current speed of the vehicle.

1 1. Light module according to claim 9, characterized in that the absolute current levels of the pulsed current due to the weather conditions in which the vehicle is adjusted.

12 light module according to claim 9, characterized in that the absolute current levels of the pulsed current due to the current temperature of the semiconductor light sources are adjusted.

13 light module according to claim 9, characterized in that the absolute current levels of the pulsed current are adjusted depending on the cumulative duration of the at least one semiconductor light source.