DE102012014645A1 - Multilayer image display device for use in e.g. notebook, has polarization filter assigned to liquid crystal layer, where light from light source is guided through retardation element before light reaches observer - Google Patents

Abstract

The device has a light source and two liquid crystal layers (14, 24) arranged along a longitudinal extension direction from a rearside to a frontside of the device. A polarization filter (10) is assigned to one of the liquid crystal layer and another polarization filter (22) assigned to another liquid crystal layer, where the light from the light source is guided through an optical and/or electro-optical retardation element before the light reaches an observer. The retardation element comprises a flat, dimensionally unstable and transparent element. An independent claim is also included for a method for operating of a multilayer image display device.

Description

The invention relates to a multi-layer image display device having a rear screen and at least one front screen, the arrangement being such that an image (background image) generated by the rear screen is visible through the front screen and the front screens, respectively.

Such image display devices, which are also known as multilayer displays, are preferably used in video game consoles for so-called arcade games (also referred to as arcade machines) are used and contribute there by their 3D-like multi-level image display to increase the fun on the game. Of course, other, more serious applications are conceivable and already under development.

Hitherto known multi-layer displays are constructed almost exclusively on the basis of liquid crystal screens (LCDs) whose individual pixels act as a kind of colored filters, and which are illuminated by a arranged behind the rear screen light source. The LCD technology is largely mature and relatively inexpensive available. Nevertheless, there are fundamental disadvantages that have a disadvantageous effect especially when used in multilayer displays. These include, in particular, comparatively high transmission losses due to the absolutely necessary polarization filters which add up correspondingly in the case of several screen layers arranged one behind the other. The remedy is provided by a high-intensity light source which, however, releases a high heat loss, which in turn adversely affects the life of the screens. Furthermore, there is a principal problem in the display of bright foreground objects against a dark background image, because the front screen is only illuminated by the amount of light that is transmitted by the rear screen. Through some tricky measures, these disadvantages can be mitigated, but not eliminated.

The present invention is therefore based on the object, a multi-layer image display device of the type mentioned in such a way that the disadvantages are avoided. In particular, the image display should be fundamentally improved in terms of brightness, contrast and color saturation for any foreground objects, even in dark and monochromatic background images.

This object is achieved by the features of claim 1.

Accordingly, it is provided that the front screen or at least one of the front screens an emissiver, d. H. luminescent screen is.

If the front screen itself emits light, so is not dependent on a backlight for image generation, but still - especially in the wavelength range of visible light - is so optically transparent (transparent) that he lets the image produced by the rear screen shine through in a perceptible way completely new possibilities of two- or multi-layer image display and the associated electronic control. In particular, it is then possible to display a bright foreground object on the front screen level, even if the background image on the rear panel level is completely dark over the entire screen extent. The same applies to the color representation when the front screen is able to emit colored light, so for example when playing a bright green foreground object against an intense red background image.

In a particularly advantageous embodiment of the front screen is an OLED screen, so based on the technique of organic light-emitting diodes (OLEDs), which are made in particular as thin-film elements using organic semiconducting materials, and the matrix are combined into a screen with individually controllable pixels. Such monitors have comparatively low response times and, due to their high energy efficiency during operation, generate only little waste heat. With increasingly better encapsulation of the elementary image cells, a long service life of the OLEDs with little aging is to be expected in the future. Above all, however, it is now possible to produce highly transparent OLED layers and accordingly also screens which - at least in the non-emitting state - attenuate the intensity of light transmitted from behind only slightly. Especially this property, which can be disturbing in other contexts, proves to be advantageous in the front layers of a multilayer display, since the background image has to have only a comparatively low brightness and still be well perceivable through the front screen.

Possible alternatives to OLED screens are LED screens, PDPs, field emission screens (FEDs), electroluminescent screens, and surface-conduction electron emitter screens (SEDs), provided they are designed and manufactured to be transparent.

Even if the emitting elementary cells of these screen types should not have the desired optical transparency, it is possible to provide comparatively highly transparent intermediate spaces of suitable extent between the unit cells, accepting a correspondingly lower pixel density and correspondingly lower resolution Light from the rear screen position can pass through the thus designed front screen position and the background image remains perceptible as such. Additionally or alternatively, suitably designed apertures (free openings) may also be present in the respective screen of the front layers, for example in the form of flat, pixel-free areas or the like. Furthermore, with the aid of suitable optical devices such. B. lenses, prism, and / or mirror systems a light deflection around optically opaque screen areas of the front screen layer (s) to be provided around, so that the blocked without such measures light components can still be used.

In one possible variant, the rear screen is a non-emissive screen, which is illuminated in operation by a light source located behind it. In particular, it may be a liquid crystal display (LCD) or thin film transistor (TFT) screen with LED backlight (LED backlight). Alternatively, for example, cold cathode tubes, electroluminescent films or other bulbs can be used for backlighting. Another variant is the known as edge light lighting, which emanates from the edge of the screen and optionally guided via optical fibers to the center.

In an alternative variant, the rear screen is also an emissive screen, in particular an OLED screen or a plasma screen.

It is within the meaning of the invention and of the claim wording to provide an image display device with three or more layers of screens arranged behind one another, wherein at least one of the arranged in front of the rearmost screen screens is an emissive screen in the above sense. This advantageously applies to all screens arranged in front of the rearmost screen and possibly also to the rearmost screen. However, it is also possible, for example, to arrange emissive and non-emissive screens alternately (alternately) or to select other combinations and sequences.

In a modification of the basic idea, one of the screens further back could emit light in a wavelength range outside the visible spectrum instead of / in addition to visible light, which is at least partially transmitted by a screen in front of it and thereby converted into visible light.

The advantages achieved by the invention are, in particular, that the self-illuminating and at the same time predominantly transparent design of at least one of the front screens in a multilayer display eliminates fundamental limitations of existing LCD systems and novel possibilities for extremely luminous, high-contrast and color-intensive 3D representations be created with parallax effect, without requiring particularly bright separate light sources for backlighting.

Common to the screens of such technologies that they must be at least partially transparent for use at least partially for the image information of the rear screens when using as front screens - such as transparency, proportionate aperture or aperture pattern, or by means of suitable optical devices such. B. lens, prism, and / or mirror systems. With the use of more than two layers, an actually volumetric image display can be achieved, in which each viewer receives different image information from different angles simultaneously depending on the viewing angle without further aids such as optical barriers, (shutter) glasses, polarization filters, eye tracking or the like, whose depth resolution depends significantly on the number of screen layers used.

Various embodiments of the invention are explained below with reference to drawings. In each case schematic and highly simplified representation:

1 a two-layer image display device according to a first variant of the invention,

2 a two-layer image display device according to a second variant of the invention, and

3 a three-layer image display device as an example of another variant of the invention.

In the 1 2-layer image display device shown in cross-section 2 points in the direction of the viewer 4 seen a front screen 6 and a back screen 8th with substantially the same dimensions, which are arranged at a distance d one behind the other. The two screens 6 . 8th are aligned in a row, that of the rear screen 8th generated background image through the front screen 6 through to the viewer 4 is visible. In doing so lie down on the front screen 6 represented foreground images or foreground objects in a sense above or before the background image, so that - at least in moving subjects - the impression of a 3D representation with spatial depth and parallax effect arises.

At the in 1 variant shown is the rear screen 8th an LCD screen illuminated by a light source behind it 10 , is illuminated, for example in the form of an LED panel. The back screen is therefore not self-luminous, but rather represents an array of individually controllable color filters that produce more or less light of corresponding color from the light source 10 towards the viewer 4 let through, which results in sufficient observation distance in a known manner, the desired image impression. The front screen 6 however, it is designed as a self-luminous, optically transparent OLED screen with an array of individually controllable organic light emitting diodes with a suitable emission wavelength, ie color. For the generation of the foreground image it is therefore not necessary that the rear screen 8th Light from the light source 10 lets through. Rather, the background image can be completely dark. However, if there is a background image of appropriate brightness, then it seems due to the optical transparency of the front screen 6 through it, and is the more noticeable the lower the local emission power there is. By suitable preparation of the foreground image and the background image in one of the two screens 6 . 8th upstream picture computer 12 , the part of the image display device 2 or separated from it, complex 3D scenarios can be represented.

In the 2 variant shown differs from that in 1 in that the rear screen 8th itself is an emissive screen, such as an OLED screen or a plasma screen. A separate light source for backlighting is therefore not needed. The image calculator 12 has been omitted in this illustration.

In 3 Finally, as another example, a three-layer image display device 2 with a rear screen 8th and two screens in front of it 6 . 6 ' shown, wherein at least one of the two front screens 6 . 6 ' an optically transparent, self-luminous screen in the above sense. In particular, both front screens can 6 . 6 ' be transparent and self-luminous.

Of course, even more display layers can be provided.

LIST OF REFERENCE NUMBERS

2

Image display device

4

observer

6, 6 '

front screen

8th

rear screen

10

light source

12

calculator

d

distance

Claims (6)

Multi-layer image display device ( 2 ) with a rear screen ( 8th ) and at least one front screen ( 6 . 6 ' ), wherein the arrangement is such that one from the rear screen ( 8th ) generated image through the front screen (s) ( 6 . 6 ' ) is visible, characterized in that at least one of the front screens ( 6 . 6 ' ) is an emissive screen. Multi-layer image display device ( 2 ) according to claim 1, wherein the at least one front screen ( 6 . 6 ' ) is an OLED screen. Multi-layer image display device ( 2 ) according to claim 1 or 2, wherein the rear screen ( 8th ) is a non-emissive screen which, in use, is illuminated by a light source located behind it ( 10 ) is illuminated. Multi-layer image display device ( 2 ) according to claim 3, wherein the rear screen ( 8th ) is an LCD screen. Multi-layer image display device ( 2 ) according to claim 1 or 2, wherein the rear screen ( 8th ) is an emissive screen. Multi-layer image display device ( 2 ) according to claim 5, wherein the rear screen is an OLED screen or a plasma screen.

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