DE10357047A1 - Device for displaying information on a transparent substrate - Google Patents

Abstract

The present invention relates to a device for projecting information onto a transparent substrate, such as viewing windows of a vehicle, in particular a windshield of a motor vehicle, wherein a spectrally selectively reflecting coating system of two or more layers is arranged on or in the projected for the surface of the substrate , which reflects light from one or more monochromatic light sources, as well as the use of the device according to the invention for head-up displays.

Description

The The present invention relates to a device for displaying Information on a transparent substrate, in particular for Displaying information on windows of vehicles such as windshields of vehicles, also called Head-Up Displays (HUD).

Head-up displays (HUD) represent an innovative way of visualizing information for the leader of a Vehicle (rolling stock such as railways, motor vehicles, aircraft, watercraft, Construction vehicles, etc.), which allow the transmission of information, without the leader distract from his duties. The basic idea is the projection or insertion of the information to be displayed in the field of view of Driver, so as to avert the driver from his duties and therefore one To reduce dead time in its reaction or to be able to avoid it.

For this be different approaches which can be divided into two categories: projections on the retina (through helmet visors, prisms, etc.) and projections virtual images on transparent image surfaces (for example, windshield by train and car). This invention relates to the second embodiment the projection directly onto the glazing of the cockpit of one Vehicle.

One fundamental Problem in the realization of such projections is the required intensity of the projected Picture to opposite the avoidable bright environment (summer, daylight, etc.) for the driver continue to be recognizable, so a sufficient contrast to deliver.

When Projection source (lamps of the projection system) are increasing Light-emitting diodes and laser diodes or laser sources in the broadest sense used and also for the realization o.g. HUD favors.

One However, the problem of these light sources is the limited available Intensity, which are subject to developmental limits. In addition, for the light source needs a deflection unit, which is similar to the ray of light the color TV over the screen moves. The term "screen" is also used in the following Meaning representative of Windshields or other glazing used by the driver looks.

moreover is an optic needed which are the primary valences (for example, a red, green one and blue laser) in a laser beam. The overall system (Optics) currently indicates only insufficient Efficiencies of up to 30%. Add to that the poor reflectivity of a Glass sheet (n ~ 1.45) against air (n ~ 1) of about 4%.

The The system is therefore not strong enough to fight against the ambient light to achieve a significant contrast.

Alternative systems also have problems with regard to the enormously high applied intensity for sufficient contrast and the associated active cooling that becomes necessary ( DE 10016817A1 ).

There are already various proposals with regard to possible implementation forms for HUDs, which in the broadest sense, however, the arrangement of the projection unit ( DE 10144491A1 , WO 02/35276 A1, DE 10135342C1 respectively. DE 4211728A1 in combination with a holographic element), the implementation of additional elements in the field of vision of the driver (WO 02/35276 A1) and changes of a geometric nature on the disc (such as insertion of a wedges, etc.) to avoid ghosting by reflection at the two interfaces Glass pane (US 2002 / 0008926A1, US 2003/6534152B2, WO 94/00787) relate. These applications do not relate to the realization of a sufficiently high-contrast image for the driver.

With regard to this topic, there are also publications based on reflection-enhancing filters (US 2003 / 0035939A1, US Pat. EP 1283432 A2 ) or locally toned disc ( DE 19816647 A1 ) to improve the contrast.

The present invention relates to a device for projecting information onto a transparent substrate, wherein a spectrally selectively reflecting coating system is provided on or in the projected for the projection surface of the substrate, the light of one or more monochromatic Reflected light sources.

at the transparent substrate is preferably one Lens of a vehicle, such as a motor vehicle, a rail vehicle, a ship or an airplane etc.

Preferably this is a windshield or a rear window of a motor vehicle.

The transparent substrate may be made of glass or another suitable for this purpose transparent material like a plastic like polycarbonate.

Of the As used herein, "glazing" does not encompass this only substrates made of glass, but also of other suitable ones transparent materials.

below The present invention will be explained in more detail with reference to the attached figures.

It show here:

1 a theoretically optimal reflection spectrum;

2 a spectrum of a spectrally selective reflective coating system which is an 11-layer dielectric interference filter;

3 another example of a spectrum of a 12-layer dielectric interference filter; such as

4 a flowchart for a genetic algorithm for calculating a spectrally selective reflective coating system for the device according to the invention.

The inventive solution based on the use of spectrally selective reflective coating systems, such as dielectric interference filter, and others optical thin-film filter systems, e.g. with layers of cholesteric polymers or LCDs which spectrally selective, it allows the reflectivity of an interface significantly to increase.

In contrast to the applications US 2003 / 0035939A1 and EP 1283432 A2 an essential aspect of the invention is the spectral selectivity of the reflection enhancement.

basic idea is the most selective and possible Narrow-band reflection of equally narrow-band primary valences of a projection system, as in the favored ones mentioned Forms are present on the windshield or glazing the driver's pulpit. Hereby, the system can with the above embodiments for the Avoidance of ghosting can be combined appropriately.

The inventive device is particularly suitable for the front projection with light of one or more monochromatic Light sources, for example laser light.

to Realization of the spectrally selective reflection can be a dielectric Filter system can be used as it is in its calculation and Function e.g. in C. Rickers, M. Vergohl, "Spectrally selective reflecting thin-film filters for laser display technology ", Thin Solid Films 442 (2003) 145-152 [1] and C: Rickers, M. Vergöhl, "Design and manufacture of spectrally-selective reflective coatings for the use with laser display projection screens ", Appl. Optics 41 (16): 3097-3106, 2002, [2] is described. These documents are for the present The invention is incorporated by reference in its entirety and by the invention by reference.

Of the described there, basically identically constructed filter is used the reduction of the reflection in large parts of the visible spectral range with simultaneous increase the reflectivity at the wavelengths the laser emissions.

Examples of such filter systems are also in DE 102 45 881.2 and DE 197 47 597.3 which is also incorporated herein by reference in its entirety and which is also incorporated by reference for purposes of the invention.

The spectral selectivity These coating systems rely on interference effects of a incident light wave with itself by dividing into partial waves at several interfaces and inducing a phase shift through different ones Propagation rates, as described in [1] and [2] is.

The thereby increased contrast in simplified terms, it is based on reducing the reflection of Ambient light upon receipt of reflection from projected light.

The principle is in 1 shown in more detail. 1 shows a theoretically optimal reflection spectrum, where the emission of the projection system is marked vertically (narrowband primary valences, here laser emissions at the wavelengths 446 nm, 532 nm and 628 nm for blue, green and red).

As in 1 As shown, an ideal filter would narrowband the primary valences of the projector in the form of a rectangular profile, while maintaining 100% transmission in the remainder of the spectrum.

by virtue of limited available standing layers or total thickness of the filter system is such However, spectral characteristics technologically not feasible today how closer also under the aforementioned references (1), (2).

Of the Compromise therefore goes in the direction of reducing the reflected Intensity, Broadening of the reflection peaks, with a loss of contrast is accepted, as well as increased Reflection between the peaks.

For the device according to the invention, a spectrally selectively reflective coating system can be used, as described, for example, in the abovementioned German patent application DE 197 47 957 A1 in International Application WO 98/36320 and in the German Patent DE 199 01 970 C2 is described.

Thus, the spectrally selectively reflecting coating system can be formed from one or more cholesteric polymer layers as described in US Pat DE 199 01 970 C2 are described. Here, spectral selectivity is achieved based on the properties of cholesteric polymers having as a single layer the ability to circularly polarized light of a given handedness (that is either right or left circular) and thus each 50% of the unpolarized light in a certain wavelength band Δλ to reflect. For optimum reflectivity, the coating system should have at least 2 enantiomeric cholesteric polymer layers with appropriate selectivity for that wavelength for each selected wavelength. Since cholesteric enantiomers reflect oppositely circularly polarized light, in this case, both the right and left circularly rotating portions of the unpolarized light are reflected in the respective wavelength band.

One for RGB radiation Therefore, a particularly suitable coating system should at least have six layers of cholesteric polymers, wherein each two adjacent layers are enantiomerically to each other and reflect the blue, red or green light, so that altogether a reflection of approximate 100% for all RGB wavelengths can be achieved.

The spectrally selective reflective coating system can be made from a multilayer coating system of at least two dielectric materials different optical density or with different Refractive index be constructed. The at least two layer materials are applied alternately on the substrate, so each one low-refractive layer and a high-refractive layer alternately are arranged on the substrate. The respective layer thicknesses of high or low refractive layers of a system can be the same or different. For example, one or more periods each of a high refractive index layer having a first layer thickness and a low refractive layer having a second layer thickness be provided. In this case one speaks of periodic arrangement.

The Thicknesses of the high-refractive and the low-refractive layer can however also vary; in this case one speaks of non-periodic Arrangement.

Examples of suitable dielectric materials for the above coating system of layers with low and high refractive index materials are the oxides or nitrides of silicon, aluminum, Titanium, bismuth, zirconium, cerium, hafnium, niobium, scandium, magnesium, tin, zinc, yttrium and indium. Preferred examples of low-index materials are SiO ₂ and MgS ₂ and in particular Al ₂ O ₃ .

Preferred examples of high refractive index materials are titanium oxide and niobium oxide as well as Si ₃ N ₄ .

Examples of preferred combinations of high-index and low-index materials are silicon dioxide as the low-refractive index material and titanium dioxide in the rutile phase and in the anatase phase as the high-index material, and the combinations SiO ₂ / Si ₃ N ₄ and in particular Al ₂ O ₃ / Si ₃ N ₄ .

Another example of a suitable material is the variable layer thickness system Si ₁ -x-y O _x N _y , where the refractive index can be adjusted by varying the nitride concentration.

such Coatings from a multilayer coating system from a sequence alternating high and low refractive dielectric materials act as interference filters, with which selectively the wavelengths of the Projection light to be reflected.

Methods for producing the multilayered layer systems of dielectric materials are known per se and, for example, in DE 197 47 597 A1 and WO 98/36320. Examples of suitable coating methods are vacuum coating methods such as magnetron sputtering and electron beam evaporation.

In 2 a practically feasible reflection spectrum for a dielectric filter system of 11 layers is shown. The transmission is here 100-R and thus it is in the areas outside the laser emission (vertical markings) about 90 to 95%.

As materials for the layers SiO ₂ and Si ₃ N _{4 were} used, which have been applied to a sheet of polycarbonate.

Different as for the use as a screen is for the use in viewing windows the adequate transmission of the spectral selectively reflective coating is an essential criterion.

So should be sufficient when used in viewing windows for vehicles Be assured of transmission so that the driver's view of the surroundings is not affected.

For example the transmission of a windshield in the automobile must be certain for safety reasons Meet standards. An increase the reflectivity would be therefore in view of the desired transmission counterproductive.

Next The possibility maintaining a given minimum transmission can an optimization for different projection angles depending on the installation geometry as well as the oppression or at least as possible extensive suppression the so-called color flop effect desirable be.

Under Color flop will be a change the color impression in the viewer understood by a change of the viewing angle. However, the color flop effect only of minor importance when used in head-up displays, because the position of the viewer and thus the angle of view Is essentially fixed.

ever as needed, it may also be desirable its other properties for to adjust the coating.

Preferably contains the device according to the invention in particular a spectrally selective reflective coating system, that is optimized in terms of being next to it as possible high contrast with sufficient transmission the best compromise from small layer thickness, small number of the layer materials to be used and a small number of individual layers.

According to the invention therefor spectrally selective reflective coating systems uses the consist of at least two layers.

An inventively suitable coating system, the above-mentioned Randbedin can be achieved by using a genetic algorithm as described in (1), (2) and in the German patent application 102 45 881.2, obtained by a rating by means of the color matrix or by other software optimization programs.

in this connection is the colorimetric evaluation with an optimization algorithm combined, for the optimization does not require a given initial design as input because it already essentially reproduces the target spectrum. By combination leave this algorithm with colorimetric evaluation procedures the optical inventive Coatings obtained whose properties in terms of desired Boundary conditions are optimized.

With This method can, in particular, taking advantage of the advantages as mentioned in (1) and (2), namely consideration of eye sensitivity for a optimal result in compliance with the respective boundary conditions, additionally a suitable rating for the minimum transmission already in the development process of the coating system considered become.

moreover can be the boundary conditions for other desired properties optimize. So is an integration of the spectral characteristic of the coating system in the spectral properties of others in the substrate used filter systems or tints in the evaluation of the design possible.

In order to Is it possible, also tinted in the case Viewing windows such as windscreens with solar control, color tint etc., integrate the coating system so that the coating system provided area the windshield from outside the vehicle is largely or not visible.

consequently can according to the invention Applying the genetic algorithm and making use of available materials, Layer number and total thickness of the coating system the best possible reflectivity, their valences of the spectral sensitivity of the human Eye are adapted to be realized.

to Production of the device according to the invention will be the desired one Coating system by a suitable coating method as they are well known, with the desired material combination applied to the intended transparent substrate.

The Substrate may be rigid or flexible.

So can the spectrally selective reflective coating system on a flexible film can be applied, which subsequently or laminated or introduced into the viewing window. This procedure is especially in the case of strongly curved lenses advantageous.

Especially can the inventively used Coating system are applied to a wedge film. Further The coating can be done on multiple interfaces, resulting in increase the total reflection leaves.

By Combination with a wedge foil or glazing with wedgeartigem Cavity allows effective suppression of ghosting.

Further is the use of the device according to the invention also for substrates possible, the with additional Functional elements or functional layers are provided.

For example can the device of the invention for windshields be used in addition with a heat-resistant Layer are provided or with a transparent conductive layer from, for example, TCO materials, how it can be used to heat the pane.

Hereinafter, the operation of the genetic algorithm for optimizing spectrally selective reflective coating systems as they are suitable for the device according to the invention, with reference to the flowchart in 4 explained in more detail.

The functioning of the genetic algorithm is based on the evolution and recombination strategies of nature. The basic idea is that out of a number of individuals, which together form a generation, only the individuals are selected to generate a new generation, which have the best properties in terms of their environment. For the present case is under a Indivi duum a layer system understood with its layer thicknesses and material properties. The parameters of the layer system, such as layer thicknesses and materials, are referred to as genes. The algorithm first generates a population of individuals by randomly assigning materials and layer thicknesses (in 4 These individuals are then rated and sorted by quality, followed by a loop consisting of the steps recombination, mutation, evaluation and selection (selection of the better individuals, ie layers), discarding bad layers. By repeatedly performing the loop, an improvement in the quality of the population on average and that of the best individual is achieved absolutely until an optimum is achieved.

For the production the invention used Coating systems, the evaluation and thus optimization based on colorimetric considerations. By the rating based on the colorimetry, can be set to a default of a discrete target spectrum are dispensed with.

wobei Y der Normfarbwert ist und damit ein Maß für die Helligkeit des Reflexionsspektrums. k gibt den Kontrast an, den die Bildwand für Primärvalenzen der entsprechenden Wellenlängen gegenüber Umgebungslicht erzielt.The contrast arises here

where Y is the standard color value and thus a measure of the brightness of the reflection spectrum. k indicates the contrast achieved by the screen for primary valences of the corresponding wavelengths to ambient light.

und σ_R die Standardabweichung des Reflexionsvermögens und C ein empirischer Faktor ist.For the implementation of the algorithm, a modified formula (1) is used for the evaluation of the contrast, the sum being replaced by a product:

and σ _{R is} the standard deviation of reflectivity and C is an empirical factor.

For the increase of Contrasts is less a particularly high reflection in the field of Laser wavelengths decisive, but rather the lowest possible reflection in the spectral range outside from that.

in the genetic algorithm can reduce this effect by influencing the Weighting to be taken into account, with which the underground is suppressed becomes. This is done by equating the exponent of Y in Equation (2) is varied.

Corresponding can the desired or necessary transmission can be set.

For the minimization or elimination of the color-flop effect is the layer system be interpreted that by amendment of the observer angle caused a change in the reflected intensities for all wavelengths of the Projection light is the same. As a basis for evaluation by the algorithm be for this the spectra of one individual (shift system) for different ones Viewing angle calculated and the change of the reflected intensities for the wavelengths of primaries using standard deviations of these values.

Further If necessary, adjust the color neutrality of the picture by white balance take place, the intensity of the light reflected from the image wall of one of the wavelengths of Primary valences (red, Green Blue) with the intensity of the monochromatic light of the corresponding wavelength as it is emitted from the projector.

Based The procedure described above is carried out with the aid of genetic algorithm is an evaluation of a shift system that without a firm requirement for a discrete reflection spectrum and increases the contrast, wherein at the same time the color flop is suppressed.

By the described combination of a genetic algorithm with one on the Colorimetry-based evaluation will be spectrally selective reflective Coatings obtained which significantly improved contrast at the same time optimally lower. Total layer thickness and number of Single layers included.

For example can hereby coatings with a contrast of at least 2.5 at a thickness of the total layer of less than 4.5 microns achieved become.

In 3 schematically shows the spectral profile of a spectrally selective reflective coating, which has been obtained according to the genetic algorithm described above.

It is a coating of a layer system of low and high refractive dielectric materials. The coating consists of twelve individual layers, with SiO ₂ as low refractive index material (n = 1.46) and Si ₃ N ₄ as high refractive index material (n = 2.05) deposited on a glass substrate

The layer structure starting from the glass substrate upwards is as follows:
Glass
Si ₃ N ₄ 239 nm, SiO ₂ 210 nm,
Si ₃ N ₄ 324 nm; SiO ₂ 319 nm,
Si ₃ N ₄ 435 nm, SiO ₂ 197 nm,
Si ₃ N ₄ 22 nm, SiO ₂ 241 nm,
Si ₃ N ₄ 72 nm, SiO ₂ 372 nm,
Si ₃ N ₄ 249 nm, SiO ₂ 35 nm.

These Coating shows a contrast enhancement k of 3.55.

Claims (13)

Device for projecting information onto a transparent substrate, characterized in that a spectrally selectively reflecting coating system is arranged on the projection surface of the substrate, which reflects light from one or more monochromatic light sources, wherein the spectrally selectively reflecting coating system consists of two or more Layers exists. Device according to claim 1, characterized in that that the spectrally selective reflective coating system Dielectric interference filter made of two or more layers from optically different dense materials, from two or more Layers of cholesteric polymers or an LCD system is. Device according to Claim 1 or 2, characterized that the thicknesses of the individual layers are the same or different or the system is a combination of layers with the same and different thicknesses. Device according to one of the preceding claims, characterized in that the transparent substrate is a viewing window of a vehicle. - Contraption according to claim 4, characterized in that the vehicle is selected under a motor vehicle, a rail vehicle, a ship or an airplane. Device according to one of the preceding claims, characterized characterized in that the transparent substrate is made of a material selected under glass and a transparent plastic. Device according to one of the preceding claims, characterized characterized in that the spectrally selective reflective coating system is applied to a transparent film, and the film with the spectrally selective reflective coating system on or in the transparent substrate is arranged. Device according to one of the preceding claims, characterized characterized in that the transparent substrate is tinted, especially a tinted one Windshield is. Device according to one of the preceding claims, characterized characterized in that the viewing window with one or more further Provided functional layers for modifying the properties of the lens is. Device according to one of the preceding claims, characterized in that the spectral selectively reflective coating system on the side facing away from the projection light side with the human eye is essentially not visible. Use of spectrally selective reflective Coating systems with two or more layers for head up displays. Use of spectrally selective reflective Coating systems with two or more layers for one device for projecting information onto a transparent substrate, in particular a viewing window for Vehicles. Use of a spectrally selective reflective Coating of two or more layers for windshields of vehicles, in particular of motor vehicles.