EP1082640A1

EP1082640A1 - Transverse projector

Info

Publication number: EP1082640A1
Application number: EP99920555A
Authority: EP
Inventors: Jan Hess
Original assignee: Individual
Current assignee: Individual
Priority date: 1998-04-08
Filing date: 1999-03-25
Publication date: 2001-03-14
Also published as: WO1999053375A1; DE19913508A1

Abstract

The invention relates to a device in which the light bundle of the projector propagates approximately parallel to the image area and presents an anamorphotic compression which strongly compresses the bundle in a dimension perpendicular to the image area. A mirror which is slightly parabolic on one side is positioned at the edge of the image area and reflects the image back onto said image area. In this way the anamorphotic compression is compensated by the acute angle of incidence of the light onto the image area.

Description

description

Cross projector

The invention relates to a device for

Presentation of primarily video images by projection, housed in a particularly flat housing.

Projection television sets have been used as rear projectors

S long available in stores. Their market niche is the large picture area that tube TV sets cannot achieve with reasonable effort. In this way, they form the transition between "normal" television sets and cinema-like video projection. The attractiveness of these devices could be significantly increased if their bulky appearance could be overcome and if they, if necessary also mounted on the wall, left a more subtle impression. In order to realize a small housing depth, it is necessary to let the pro ector light hit the image area at a very flat angle S. Following this method, several patents have already been published. The device described here features the following features. The transverse projector Fig.l has on the one hand the projector part l, as is usually the case, consisting of a lamp, concave mirror, condenser lens, image element (s) and the projection lenses. The image element can be based on a wide variety of technologies, CD / DRI panel, DLP chip, etc. The defined inclination of an LCD panel in the beam path, for example, can be done with the least effort over the entire range

Correct depth of field changing IS image area. However, other precautions on the optics are also conceivable. The projector light bundle, which moves approximately parallel to the image area 4, strikes the deflecting mirror 2 in an anamorphic manner. For this, the light runs through the project

Partial system of cylindrical lenses 3, which acts like an inverted telescope and reduces the angle, but only one dimension, that which is perpendicular to the image plane and which is decisive for the depth of the housing, Fig. 1, The dimension of the projector light bundle

35 parallel to the image area 4, however, does not affect the anamorphic lens system. So the light beam on mirror 2 has the width of the screen side on which it is located. Its ultimate expansion into the second anamorphic compressed dimension is due to the perspective distortion,

5 caused by the very flat impact angle of the

Light on the screen. The deflecting mirror 2 is, in contrast to the otherwise proposed design forms in such devices, very inexpensive. The narrow side perpendicular to the picture surface is flat, its long side has

Λθ a slight curvature in parabolic form, but a simple constant bending radius is also sufficient. In the fanned-out plane, the light is thrown onto the screen. This can be located on the back as well as on the front of the housing Fig. 2/1.

Λξ If it is in the front, the greatest possible utilization of the light from behind is achieved by the fact that the transparent screen panel has a large number of prism-shaped elevations on its inside Fig.l. These then almost completely direct all light in the direction

2.0 of the viewer. A picture surface on the back and reflecting the light only makes sense if two partial images of polarized light are to be reproduced. For this purpose, the cross-projector has two projector parts l, each of which is provided with polarization optics (prism, thin glass pane package, etc.) S. If their polarized light is then rotated by 90 ° relative to one another, the viewer can achieve very realistic spatial images by using polarization filter glasses by separating the two perspectively shifted partial images

30 earth. Because a diffuse reflection destroys the polarity of the light, the image surface must have special properties, such as that its surface is metallic or reflects at least in a similar way. The flat angle of incidence of the light probably makes a structural

35 ^tur the screen surface ation necessary Fig.2.

For example, the structuring with a large number of partial cylinders and partial spherical cutouts receives that for the polar. Light necessary way of reflection, although the light is fanned out at a wide angle. The distortion caused by the shape of the deflecting mirror 2 can be compensated for by a one-sided, slightly concave shaping of the image area 4, ie the lines curving towards the center of the image area in the direction of the mirror then meet the image area after a correspondingly extended distance. In the case of a 3D projector model equipped with a rear screen, this structure even accommodates working with polarized light. The front screen is slightly convex on one side towards the viewer. The screen is always curved in its dimension parallel to the mirror 2 Fig.3.

It is also conceivable to save the anamorphic lens system 3. It would suffice for this that the picture element in the projector part is already made in accordance with the desired anamorphic distortion, e.g. has a strongly rectangular shape. However, since projectors require a point light source, the problem of light utilization arises here. The image area could also be made completely flat if a corresponding electronic correction on the image element counteracts the mirror distortion. However, such measures result in fraying of the lines.

Claims

4 patent claims

1.) Cross-projector for generating large-format images by means of projection within a very flat housing, characterized in that the projector light bundle which extends approximately parallel to the image surface is a strong one

5 has an anamorphic compression in its dimension perpendicular to the image area - caused by a system of cylindrical lenses which adjusts the image angle on one side and which adjoins the projector part - before it falls on the deflecting mirror located at the edge of the image area,

40 which has the property of being flat in its side perpendicular to the image surface, but having a parabolic contour or one of constant curvature (cylinder cutout) in its side running with the image surface edge, which causes the fanned-out projector light beam

Λζ dimension aligned parallel to the picture surface, which is on the front, -od. The rear of the cross projector.

1.1) Cross-projector according to claim 1, characterized in that the anamorphic light beam compression is not

10 is carried out by a system of cylindrical lenses, but solely by means of a picture element (e.g. LCD panel) which already has the desired compression.

1.2) Transverse projector according to claim 1, characterized in that two projectors located in it and each provided with a polar riser each reproduce perspectively slightly shifted partial images in polarized light rotated by 90 ° relative to one another, which the viewer uses polarizing filter glasses convey a spatial image impression.