DE102004042648A1 - Device and method for displaying a static or moving picture uses screen, which has a structure that defocuses the laser beam - Google Patents

Abstract

The invention relates to a device and method for displaying a static or moving picture, wherein the inventive device comprises a laser light source and a screen and is characterized in that said screen has a structure at which the illuminated parts simultaneously reflect or transmit light in different directions inside a beam width to reduce or eliminate speckle interference.

Description

The The invention relates to an apparatus and a method for display static or moving images with a laser light source and a Screen. Such methods offer the possibility of photos, video data or to represent numerical values on large areas. Due to the almost unlimited depth of focus of the laser light source is the application is not limited to flat screens.

The Display screens used in project processes are usually diffuse scattering, i. non-reflective surfaces. Will such a surface with irradiated by the light of a laser, speckle interference is formed. Speckle interference always occur when two coherent wave trains of the laser light be reflected at closely adjacent points. Unless this reflective Structure is smaller than the resolution of the eye, these become wave trains imaged on the retina of the viewer in one point and come there due to the high coherence length of the Laser light for interference. These interferences are the reason for this, that in a uniformly illuminated Beam spot brightness differences occur as granularity or speckled pattern are perceived. Unless the user so far away from the beam spot that the pattern stops disbanded can be, the beam spot appears with a time varying or pulsating brightness distribution.

For laser projection Static or moving pictures is primarily the high brilliance of the laser light of importance. As brilliance is in this context understood the number of photons per phase space element, i. Per Wavelength range, per spatial coordinate and per solid angle element. The great coherence length of the Laser light, which the unwanted Causing speckle effect is for Projection process of minor importance.

Around to minimize the speckle effect, it is the prior art known, either the coherence of the laser light or by sufficiently rapid temporal variation of speckle interference within the integration time of the eye the speckle contrast too reduce.

One simple method of destruction of coherence consists in the laser light through a rotating diffuser conduct. As a diffuser, for example, a glass plate is suitable with a rough surface. If the diffuser is located at the focus of the laser beam statistical phase variations are inserted into the beam during the spatial coherence remains. This allows the beam to continue to focus on one point become. Unless the unfocused beam passes through the diffuser becomes, both the spatial as well as the temporal coherence dissolved.

The DE 101 18 662 A1 discloses a screen in which the coherence of the reflected laser light is resolved by volume dispersion of the laser light in a layer of constant thickness applied to the screen, thus avoiding the speckle effect. As a scattering layer is according to the teaching of DE 101 18 662 A1 for example, polytetrafluoroethylene. The layer thickness is adapted to the coherence length of the laser light so that a reduction of the speckle effect by a desired amount occurs. Advantageously, the layer thickness is chosen to be greater than one tenth of the coherence length. Thus, this screen also provides satisfactory results only with low coherence length laser light sources. Another disadvantage is that changes to the projection unit always require changes to the screen.

From the US 5, 272, 473 It is known to couple a sound source to a screen, so that the acoustic waves generated by the sound source excites the screen to vibrate. The wave trains reflected by the vibrating screen generate different speckle interference at each instant. If the oscillation frequency is chosen to be large enough, these different speckle interferences are averaged during the integration time of the eye. Thus, the contrast between the interference maxima and the interference minima is compensated. The speckle contrast is thus reduced. The speckle contrast in this context is defined as the mean, square deviation of the intensity of each location in the illuminated object from the mean, nominated to the square of the mean. The disadvantage of this method, however, is that waves forming in the screen form and the speckle interference at the wave nodes of the screen arises with an unchanged intensity.

From the JP 2 000 81 602 A It is known to use a projection surface which has a similar structure as a liquid crystal display. The incident laser light is reflected on the molecules of the liquid crystal as well as on a conventional screen. However, when a high-frequency low-voltage signal is applied to the liquid crystal, the liquid crystal molecules vibrate at the frequency of the applied signal. As a result, varying speckle interferences are generated in the same way, which in turn are averaged during the integration time of the eye. A disadvantage of this method for the prevention of speckle interference, however, is the technological one limitation on the dimensions and the fact that such screens can not be bent or rolled up.

Of the Invention is the technical problem underlying a device for displaying static or moving images with a laser light source and a screen where no speckle interference occurring or occurring speckle interference as far as reduced are that these are not annoying anymore be perceived. The screen should be and size none restrictions subjected and universal with all types of laser light sources be usable. Furthermore, speckle interference evenly over the the whole area the screen are suppressed.

Furthermore The screen should be in a simple way with a contrast-enhancing coating be combined.

The The object is achieved by a device for displaying static or moving images with a laser light source and a screen in which the screen has a structure in which within the beam cross section At the same time, illuminated parts illuminate the light in different directions reflect or transmit. Furthermore, there is the solution of Task in a method for displaying static or moving Images with a laser light source and a screen in which At the same time the light entering the screen enters different levels Directions is reflected or transmitted.

The Screen according to the invention Can be used both as a reflective screen for reflected light projection as well as a transmitting screen for the transmitted light projection can be used. In the former case exists the structure according to the invention made of opaque Elements that reflect light on their surface. In the latter Case, the structure of the invention as well as the screen of a translucent material, which the in the back projection introduced transmitted light and on its surface in different directions breaks. Of course can the screen according to the invention a flat projection surface have or curved be.

By the structuring of the invention Image wall becomes light, which points to closely adjacent points of the screen impinged in different directions. Thus be both wave trains to impinge on different parts of the retina and are not more interference-capable. This turns the speckle contrast reduced as desired.

The Structure can be executed one-dimensionally and in the Continue the second direction in the translation-invariant plane. This gives the impression of a corrugated or trapezoidal sheet. However, the structure can also be in both directions of the screen accomplished become. In this case gives the impression of sitting on the surface Drops, balls, spherical caps, spherical discs, cones or any Freeform surfaces. At the same time, a harmonic surface modulation becomes homogeneous Angular distribution of the reflected light and an anharmonic Surface modification cause an inhomogeneous angular distribution of the reflected light.

Prefers is The relationship the structure width to the diameter of the beam cross section of the laser about 1: 1. The relationship from beam spot size to feature width is chosen in such a way that the laser light illuminates a structural element to a substantial extent, so that a broad emission of the radiated from the screen Light is given. The effect of the invention will of course also then still achieved when two structural elements illuminated in part become. To avoid, however, is the simultaneous illumination of several Elements, in turn, to send two wave trains in one Lead direction would.

The Structure width is in this case defined as the minimum length of a Translation vector, which lies in the plane of the screen and depicts a structural element in itself. The surface of the Structural elements themselves are preferably smooth, i. the roughnesses are small compared to the wavelength the laser.

Especially the lateral extent of the structure is preferred depending on the beam cross-section and / or the scan speed and / or the beam cross-section and / or the beam diameter selected. On this way it is ensured that the condition of enlargement of the Beam angle anywhere and at any time of the image projection guaranteed is. Preferred is a structure which is approximately the size of a Pixels has. Provided that the laser beam continuously over the Image wall is moved, the structure can move in the direction of movement have an extent which is determined by the speed of the Laser beam and the pixel frequency is determined. This preserves the screen an asymmetric structuring.

By the ratio of the height of the structure to the width of the emission angle of the screen according to the invention can be adjusted within wide ranges. Particularly preferred is a height to ready ratio of about 1: 8 to about 1:37. In the In this case, a light beam incident perpendicular to the screen is deflected by a maximum of about ± 40 ° to a maximum of about ± 10 °. The larger deflection angle is in principle suitable for image walls, which are viewed by a larger audience circle, such as cinema or video screens.

By Reduce the altitude to width ratio the viewing angle of the screen is reduced to about ± 10 °. Such screens are suitable for example for Head-up displays, which only a limited Addressing addressee circle and leave the environment unmolested should.

Of course you can by asymmetric structuring also a screen with asymmetric Emission can be achieved, for example, which less light the ceiling and the floor directs and yet a wide viewing angle allowed in the horizontal.

In The structure according to the invention can be produced in a particularly simple manner by lamination a film are produced on a carrier serving as a screen. The Film can, for example, by embossing with an embossing roll getting produced. The expert will of course also consider, with correspondingly soft carrier materials, these directly through an embossing roll or to structure a plane matrix by molding.

Further Production method of the structured screen according to the invention are sputtering or vapor deposition processes, galvanic processes, brushing, scrape, spray on or immersing the substrate material.

In this case can the structures by stencils or by structured photoresist masks be produced to the substrate. Also conceivable would be the laser structuring or selective etching processes. The person skilled in the art will become known from the structuring methods mentioned dependent on the structure size that's him choose the most appropriate appearing method.

On the structure according to the invention can be applied in a particularly simple manner, a coating become. This is easier, for example, by sputtering or spin-coating processes Way also on big ones surfaces possible. The contour-accurate coating of the structured screen can its properties continue to improve, in which, for example, reduced reflections or the contrast increases become.

Particularly preferably, the coating of the structured image wall is a spectrally selectively reflecting coating, in particular a coating according to the DE 199 01 970 C2 or according to the DE 197 47 597 A1 , These coatings selectively reflect the narrow band irradiated laser light and absorb or transmit most of the broadband ambient light. Thus, the contrast of the projected information is increased as desired. This is particularly advantageous because the achievable luminous intensity of the laser light sources can not compete with those of conventional projection lamps, such as halogen or high-pressure gas discharge lamps.

following the invention will be explained in more detail with reference to three figures.

1 shows a structured screen according to the invention when illuminated with a laser light source.

2 shows possible structural forms in the profile.

3 shows possible arrangements of the structural elements.

In 1 is a picture wall 1 with a structuring according to the invention 2 shown. The structural elements in this example are hemispherical on the screen 1 applied. The screen according to the invention is provided with a laser light source 3 illuminated. Here is the size of the structural elements 2 chosen such that the beam cone 5 several structural elements 2 illuminated. The laser light is at the surface of the structural elements 2 reflected. Due to the curvature of the surface, the light is reflected from adjacent points of impact in different directions. Therefore, wave trains from adjacent landing points either reach only the eye of an observer 4 or within the eye of a viewer, different points of the retina. Thus, interference of these wave trains is no longer possible and the speckle interferences are suppressed as desired.

2 shows possible structural forms in the profile. In this case, a structure is shown in Example A, which consists of closely lined up spherical caps. However, according to the invention it is also possible to arrange these spherical caps at regular, larger intervals as shown in Example B.

Example C shows structural elements with irregular intervals. If the spacing surfaces between the structural elements in example B and C are not flat, the result is a wave structure according to example D. Such a wave structure Ture can be carried out both one-dimensionally in the manner of a corrugated sheet and two-dimensional, such as an egg box. Figures I and F show structures whose raised portions have a wave, ie a sine shape, whereas the negative structures are replaced by plane surface elements.

3 shows the structural elements according to the invention in the plan view. At all in 3 Illustrated embodiments are two-dimensional structures that reduce speckle interference at all viewing angles. In Example A are round structural elements, such as spherical or sinusoidal structural elements, shown, which are lined up by simple translation of the elements by one structural width in each case. Example B shows identical structural elements, but offset by half an element width in one direction, resulting in the densest possible packing of structural elements per surface element. The spaced arrangement of structural elements, which in 2E . 2C . 2E and 2F was represented in the elevation forms the 3E and 3F ,

Depending on the desired radiation angle, asymmetrical arrangements of structural elements are also conceivable which permit a large viewing angle in one emission direction but have only a clearly limited emission angle in another emission direction. Such structural elements are in 3C . 3D . 3G and 3H shown. Again shows 3C the arrangement of structural elements which are offset by a structural element, analogous to 3A , The densest possible packing, analogous to 3B is in 3G shown. Of course, these asymmetric structural elements can be arranged at a distance, as in 3D and 3H shown.

Claims (15)

Device for displaying static or moving images with a laser light source ( 3 ) and a screen ( 1 ), characterized in that the screen ( 1 ) a structure ( 2 ), in which within the beam cross-section ( 5 ) at the same time illuminated parts reflect the light in different directions or transmit. Device according to claim 1, characterized in that the structure ( 2 ) comprises a periodic structure. Device according to one of claims 1 or 2, characterized that the ratio the structure width to the diameter of the beam cross section of the laser is about 1: 1. Device according to one of claims 1 to 3, characterized in that the lateral extent of the structure ( 2 ) is selected as a function of the beam cross-section and / or the scan speed and / or the beam diameter. Device according to one of claims 1 to 4, characterized that the ratio the height the structure to whose width is about 1: 8 to about 1:37 Device according to one of claims 1 to 5, characterized that the structure spherical caps and / or spherical discs and / or cones and / or truncated cones and / or rotational paraboloids and / or rotational hyperboloids and / or Includes ellipsoids of revolution. Device according to one of claims 1 to 6, characterized that the structure is obtainable by laminating a film on a support. Device according to one of claims 1 to 6, characterized that the structure is obtainable by molding Device according to one of claims 1 to 8, characterized that a coating is provided on the structure. Device according to claim 9, characterized in that that the coating causes a spectrally selective reflection. Device according to one of claims 1 to 10, characterized that the structure is formed as a reflection structure. Method for displaying static or moving images with a laser light source ( 3 ) and a screen ( 1 ), characterized in that at the same time on the screen ( 1 ) incoming light is reflected or transmitted in different directions. Method according to claim 12, characterized in that that at the same time incident on the screen light in at least a plane reflected in a maximum angle range of about ± 40 ° or is transmitted. Method according to claim 13, characterized in that that at the same time incident on the screen light in at least a plane reflected in a maximum angle range of about ± 10 ° or is transmitted. Method according to one of claims 12 to 14, characterized in that the beam cross-section and / or the scan speed and / or the beam diameter on the lateral extent the structure ( 2 ) is adjusted.