The invention relates to a process for producing a specified light pattern on a road using a motor vehicle headlight, wherein at least one modulated laser beam is directed onto a means of light conversion through a pivoting micromirror, and the light image produced on the means of light conversion is projected onto the road.
The invention also relates to a motor vehicle headlight with at least one modulable laser light source whose laser beam is directed onto a means of light conversion through a pivoting micromirror controlled by a mirror control, and with a projection system to project the light image produced by the means of light conversion onto the road.
The use of laser light sources in motor vehicles is at currently becoming more important, since, e.g., the dimensions of laser diodes are smaller than those of common light-emitting diodes, allowing more flexible and more efficient mounting solutions, and also allowing a substantial increase in the light beam's luminance and the luminous efficiency.
However, the known solutions do not involve the direct emission of a laser beam, to prevent the extremely concentrated high-power light beam from endangering the eyes of humans and other living things. Instead, the laser beam is converted, on an interposed converter that contains a luminescence conversion material, called “phosphor” for short, from, e.g., blue light preferably into “white” light.
EP 2 063 170 A2 discloses a motor vehicle headlight of the type mentioned at the beginning that can, to illuminate the road with a nonglare, adaptive high beam, omit certain areas depending on other road users. The laser beam is directed, through a micromirror that can move in at least two directions in space, onto an emitting surface containing a phosphor to convert the laser light into (preferably) white light. A lens is used to project the emitting surface's light image onto the road. Since the micromirror must deflect a concentric laser beam, it is exposed to a correspondingly high specific load per unit area, which makes its construction more expensive.
DE 10 2008 022 795 A1 discloses a motor vehicle headlight in which the beams of three semiconductor lasers of the colors red, green, and blue are united by an achromatic lens into a white beam that strikes a mirror that oscillates about two axes. A control device modulates the beam power in such a way that specified areas of the mirror are illuminated with specified power. In one embodiment, the mirror can be coated with a converter material. Another embodiment has a controlled micromirror array. In this embodiment, a laser beam strikes a diffuser that is simultaneously a light converter and that illuminates the micromirror array. Projection optics can project the desired image produced by the mirror array onto the road.
Quite generally, it is desired that adaptive headlight systems (AFS=Adaptive Frontlighting Systems) have more functionalities with high resolution and short reaction times. However, the known devices are either very complex or have resolution problems in at least one direction, usually horizontally. This also applies for headlights that use an LED matrix for illumination in which segments of the matrix can be turned on or off. In this case, the most favorable resolution is 1.5°.
A goal of the invention is to create a process or a headlight of the type that is the subject of the invention that has improved resolution in the horizontal direction and meets the above-mentioned requirements on AFS functions, without having a highly complex structure.
This goal is achieved with an inventive process of the type mentioned at the beginning, in which the laser beams of at least two laser light sources with a specified beam cross section are directed, through the micromirror oscillating about an axis, onto the means of light conversion to produce at least two light bands lying next to one another on the means of light conversion.
The functionality of a headlight can be considerably increased if the laser beam of at least one laser light source is fanned out into a beam band.
It is also expedient for the length of the light bands to be adjusted through the oscillation amplitude of the micromirror.
It is especially advantageous for the shape and size of the projections produced on the means of light conversion to be determined by the beam-forming optics and/or the choice of the distance of the emitting surface from the focal points of these optics.
The above-mentioned goal can also be achieved using of a headlight of the type indicated above, in which at least two laser light sources are inventively provided that have a laser control assigned to them to modulate the beam intensity, optics being arranged between each laser light source and the micromirror, each forming a laser beam with a specified beam cross section, the micromirror oscillating about an axis at a fixed frequency, the beams of the at least two laser light sources being reflected through the micromirror to form at least two light bands lying next to one another on the means of light conversion, the distance of the light bands from one another being determined by the angle between the formed laser beams of the at least two laser light sources, the length of the light bands on the means of light conversion being determined by the oscillation amplitude of the micromirror, and the width of the light bands being determined by the beam cross section.
To obtain a light image without interfering dark stripes, it is recommended that the light bands lie directly against one another, with any separation.
It is advantageous for the micromirror to be controlled through the mirror control with its mechanical natural frequency.
An expedient embodiment also allows the horizontal swing amplitude of the micromirror to be changed through the mirror control.
A practical further development of the invention provides that the fanned-out beams of the at least two laser light sources are reflected through the micromirror to form at least two horizontal light bands lying on top of one another on the means of light conversion.
An advantageous variant of this further development is for three laser light sources to be provided to form three light bands lying on top of one another on the emitting surface, it being possible for the light bands of the emitting surface projected onto the road to correspond to high beams, the light/dark boundary, and low beams.
It is advantageous for the light bands to have different heights, in order to increase the vertical resolution in the high beam area, for example.
The invention, along with further advantages, is explained in detail below using sample embodiments that are illustrated in the drawing. The figures are as follows:
With reference to
As for the laser control 3, it in turn contains signals from a central headlight control 4, to which sensor signals s1 . . . si . . . sn can be fed. On the one hand, these control and sensor signals can be, for example, switching commands to switch from high beams to low beams, or on the other hand signals that are picked up from light sensors, which sense the illumination conditions on the road.
Laser light sources 1a, 1b, 1c, and 1d emit blue or UV light, for example, each laser light source having one optical system 5a, 5b, 5c, 5d downstream of it, to give the cross sections of the laser beams 2a, 2b, 2c, 2d emitted by the laser light sources a desired shape. The optical systems 5a, 5b are expansion optics, consisting, in particular, of the expansion optics per se, as are known in the field of holography for wide expansion of a laser beam, and, on the other hand, of a light band adapter upstream of the actual expansion optics. Optics for laser beam formation are known and commercially available, for example the LINOS laser optics of the Qioptiq Group, whose delivery program comprises light band adapters for laser expansion optics. After the expansion optics 5a, 5b, there are fanned-out laser beams 6a, 6b, whose cross sections are not “punctiform”, but rather “linear”.
By contrast, the optical systems 5c, 5d for laser beams 2c, 2d are common collecting optics or scattering optics, since the laser beams 6c, 6d after these optics 5c, 5d are intended to produce “spots” at the points where they impinge, however not “lines”.
The formed laser beams 6a, 6b, 6c, 6d strike a micromirror 7 and are reflected on means of light conversion 8, in the form of an emitting surface in this example, which has, e.g., a phosphor for light conversion, as is known in the art. The phosphor converts blue or UV light into “white” light, for example. In the context of this invention, the term “phosphor” is quite generally understood to mean a substance or a mixture of substances that converts light of one wavelength into light of another wavelength or of a mixture of wavelengths, in particular, into “white” light, which can be subsumed under the term “wavelength conversion”. Here the term “white light” is understood to mean light having a spectral composition that gives humans the impression of a “white” color. Of course the term “light” is not limited to radiation that is visible to the human eye. Possible means of light conversion also include optoceramics, that is, transparent ceramics, such as, for example, YAG-Ce (cerium-doped yttrium aluminum garnet).
The micromirror 7 oscillating only about a single axis is controlled by mirror control 9 and made to oscillate at a constant frequency; these oscillations can correspond especially to the micromirror's mechanical natural frequency. As for the mirror control 9, it is controlled by headlight control 4, to allow adjustment of the oscillation amplitude of micromirror 7, even asymmetric oscillations about the axis a being adjustable. The control of micromirrors is known, and can be done in many ways, e.g., electrostatically or electrodynamically. In tested embodiments of the invention, micromirror 7 oscillates, for example, with a frequency of a few hundred Hz, and its maximum deflection is a few degrees to 60°, depending on its control. It is expedient for feedback about the position of micromirror 7 to be sent to mirror control 9 and/or headlight control 4.
Formed laser beams 6a, 6b, 6c, 6d produce, on the means of light conversion 8, namely on the emitting surface 8, which is generally flat, however need not be flat, horizontal light bands 10d, 10c, 10b, 10a, the angle of laser light sources 1a, 1b, 1c, 1d with respect to micromirror 7 being adjusted in such a way that the light bands lie on top of one another on the emitting surface and border one another, the distance of the light bands from one another preferably being zero. Corresponding adjustment of laser light sources 1a, 1b, 1c, 1d can adjust this exactly and produce, on the emitting surface, a light image 11 that is composed of light bands, in this case four light bands 10a, 10b, 10c, and 10d. This light image 11 is now projected on the road 13 as light image 11′ using a projection system 12. The use of only three laser light sources to form three light bands projected on the road is also possible, for example, since these light bands can then correspond to high beams, the light/dark boundary, and low beams (forward light).
The projections that would be seen if mirror 7 were stationary and that correspond to the respective laser beam cross section at this place are schematically shown to the right of the symbolically shown means of light conversion 8, namely the emitting surface. Laser beams 6c, 6d produce “spots” 6d′, 6c′ as projections, the size of the spots being determined in particular by the position of the emitting surface and of the micromirror 7 with respect to optics 5c, 5d.
In the drawing, it should also be pointed out that two pairs of light bands, namely 10a, 10b or 10c, 10d, are drawn the same height, however that the individual “lines” 6b′, 6a′ or 6d′, 6c′ are not the same height in practice. For example, the light band for high beams can be “higher” than that for low beams or for the light/dark boundary, whose dimension is the smallest in the height direction. If a change is made in the height of individual light bands, of course the angle of the laser or laser beams to one another must also be changed, to make the distance between the light bands equal to zero again.
Here the term “road” is a simplification, since of course whether image 11′ is actually on the road or also extends beyond it depends on the local conditions. In theory, image 11′ corresponds to a projection onto a vertical surface according to the relevant standards that relate to motor vehicle illuminating engineering. It should also be clear that the term “horizontal” should be understood in a relative meaning here, and relates to a level road or to a normal position of the vehicle. In theory, light bands 10a′, 10b′, and 10c′ of the image 11′ projected onto the road 13 should be essentially horizontal but not necessarily [completely] horizontal, which goes all the more for light bands 10a, 10b, 10c on emitting surface 8.
It is now apparent that light image 11, and thus also road illumination 11′ can, on the one hand, be changed by adjusting the oscillation amplitude of micromirror 7, which changes the length of horizontal light bands 10a, 10b, 10c, 10d and that the intensity distribution within each light band can also be changed by adjusting the intensity of the individual laser light sources 1a, 1b, 1c, 1d. In addition, it should be noted that it is possible to control high-frequency laser light sources, whether pulsed or with continuous intensity modulation, so that any light patterns within the light bands, which correspond to the respective position of the micromirror 7, are not only adjustable but rather also rapidly changeable, if a special terrain or driving situation requires this, for example, if oncoming vehicles or pedestrians are picked up by sensors and a corresponding change is desired in the geometry and/or intensity [of] road illumination 11′ in accordance with this.
On the other hand, it is also possible, as illustrated in
To project targeted points or lines, whose horizontal extension can be controlled, the laser light sources can be controlled in a pulsed manner as a function of the current position of the mirror. For example, to have light exit from the optical system only from 0° to 10°, the corresponding laser is turned off when the angular position of the micromirror corresponds to this range, and thus light is only radiated in the range from 0° to 10°.
In comparison with conventional AFS systems, the inventive process and headlight offer the advantage of allowing a very high, theoretically infinite horizontal resolution, since the light source can effectively be turned on at every point in time by analogous oscillation of the micromirror. In addition, the sharp delimitation of the cut out area of an illuminated object results in small scattered light values, which allows very good display of this area.
The result is that the mirror and laser control is a noticeably less complex than that of known solutions, in which a micromirror oscillates about two axes. The reason why is that the known solutions require mirror oscillation frequencies of about 250 Hz on the X-axis and about 10 kHz on the Y-axis to produce an image that is flicker-free for the eye. If it is assumed that a resolution of 200 pixels is necessary in practice, this requires laser pulse rates of up to 2 MHz, which can cause considerable difficulties with respect to the system's electromagnetic compatibility, and also the development of line lengths and cable routing that are expensive because these are high frequency lines.
Number | Date | Country | Kind |
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99/2013 | Feb 2013 | AT | national |
50614/2013 | Sep 2013 | AT | national |
Filing Document | Filing Date | Country | Kind |
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PCT/AT2014/050020 | 1/21/2014 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2014/121314 | 8/14/2014 | WO | A |
Number | Name | Date | Kind |
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20030001955 | Holz | Jan 2003 | A1 |
Number | Date | Country | |
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20150369440 A1 | Dec 2015 | US |