DE19853930C1 - Image projection system with active projection surface provided by reflective segments with variable reflection characteristics controlled by detected incident light density - Google Patents

Abstract

The system has a projection device (1) for forming an image onto an active projection surface (2) at which the image is optically reflected. The projection surface is divided into a number of reflective segments, each having a sensor element and a reflection element with a variable reflection characteristic, controlled in dependence on the incident light density detected by the sensor element. An Independent claim for a method for controlling an image projection system is also included.

Description

Technical field

The invention relates to a projection system with a projection surface onto which a Image can be projected by means of an imaging projection device and on which the image appears optically in reflection.

State of the art

The current projection technology comprises two components, namely an active, imaging projection device and a passive projection surface. The active pro The projection device sets an image (slide, reflected light projection, etc.) or an electronic Si  gnal (video signal, computer signal, etc.) with different techniques and opti components into a light beam transmitting the optical output signal oil bundle around. The light beam is usually highly reflective Projected onto the projection surface, which directs it towards one or more viewers. Depending on the spatial distribution to be expected, the viewers are ver different reflector materials are used, which differ in the characteristics of the wave Differentiate between oil-dependent reflection.

The projector-viewer-viewer optical system can be physically short are represented as follows:

The image visible to the viewer is given by the luminance L _out (x _out , ξ) of the projection surface, where ξ is a point on the projection surface and x _{out is} the direction from this point to the viewer.

This luminance and thus the brightness and the contrast of the projected image result from the folding of the radiance L _in incident on this point with the reflection characteristic f of the projection surface. This can be represented by the following formula:

L _out (x _out , ξ) = ∫ (f (x, ξ). L _in (x _in , ξ))

This conventional optical system projector-screen viewer is subject to an inevitable physical limitation of the maximum achievable contrast and brightness range. The minimum luminance, that is, the brightness of the dark areas of the image, is given by the general brightness due to stray light. The light reflected from a point on the projection surface and perceived by the viewer is consequently composed of a superimposition of the light beam projected onto the point by the projector and the scattered light directed at this point due to the general brightness in the room. In other words, the integral of the above formula extends over every incident direction x _in , in which neither the incident radiance L _in (x _in , ξ) nor the reflection characteristic f (x, ξ) of the material are equal to zero. If the room is not completely darkened, there is a certain radiance and the reflection characteristic must be greater than zero, otherwise the desired image could not be displayed on the projection surface. Thus, in the known optical system projector-projection surface viewer, there is always a physical limitation of the contrast and the range of brightness if the room is not completely darkened.

A further limitation of the contrast follows from the light scatter in the projection system itself, which inevitably forms part of the luminous flux even with optimal optics scattered in areas of the projected image that are actually no light or little light should get. Since the reflection characteristic is independent of the angle of incidence, this scattered light is passed on proportionally.

In summary, it can be said that this is from a projector and a projection surface existing projection system at completely darkened room allows excellent image projection, but in one room with a certain brightness of a physical limitation of the contrast and of the brightness range. While there are a lot of technical ones known projectors in order to project images that are as sharp as possible, but which are all subject to these physical limits.

In this connection, US Pat. No. 5,386,253 is to be mentioned, which describes a video projection system which, according to FIG. 1 of the document, has a projection device A, the projection light of which holds onto a projection surface B. The area intended for the viewer (DEFG) is located between the projection device A and the projection surface B. Before the projection system is put into operation, the projection device is tuned to the respective reflection properties of the projection surface B as part of a calibration for reasons of optical optimization of the image reproduction on the projection surface B. It is essential in the known system to generate a large number of correction values, which are each stored in a calibration step as a function of the reflection location on the projection surface and on the color of the back-reflected light. However, the measures proposed for improving the image quality of the video projections reflected back on the projection surface relate solely to a targeted adjustment of the projection device itself and do not provide for any manipulations on the projection surface B.

Another option for displaying images are active screens, which at are formed, for example, from picture tubes, LCD screens or the like. With Such active screens can also have sharp images in bright rooms high contrast are shown, but the maximum are related the display areas of such active screens are limited and larger together hanging display areas can only be realized with considerable expenditure be settled.

Presentation of the invention

The invention is based on the object of a projection system with a projection on surface for an imaging projection device so that also at existing stray light achieves very good image reproduction and high contrast become. In particular, it should be possible regardless of the imaging projector the image reproduction quality by targeted optimization of the projection surface ent to improve outwardly.

The object is achieved by a projection system with the features of claim 1 solved. Advantageous developments of the invention are in the subclaims given.

The projection system according to the invention has a projection surface which is in is divided into several segments, each segment with a reflection element is provided with variable reflection characteristics. As a result, the reflect Change characteristic according to the light projected onto the respective segment be changed so that with a high incident radiance, the reflectivity characteristics of the segment increased and with a low incident radiance  Reflection characteristics of the segment is reduced. As a result, due to a general brightness in the room scattered light on the Segments, on which a dark pixel is to be displayed, hardly reflect animals and the image is not affected. On segments on which a bright picture point is displayed, the projector projects light with high radiance, which is much more intense than any scattered light, which is why it is relative weak stray light, which is reflected by this segment, because of the we not significantly higher radiance of the projected light from the viewer is taken. With the active projection surface according to the invention, one of image projected onto a projection surface in a room with a projector of a certain brightness with high contrast.

The projection surface of the projection system according to the invention preferably has two se on each segment on a sensor element with which the pro on the segment jected light intensity is detected, in accordance with the detected light inks the reflection element is controlled.

According to a preferred embodiment of the invention, each sensor element is included provided a screen to keep out stray light.

The projection system according to the invention is preferably controlled in such a way that the sensor elements the radiance of the imaging projection device projected onto the respective segments beam of light captured, and that ge the radiance of the light coming from the imaging projection device radiate, the lower the reflectance of the respective segment is set so that the reflection of stray light coming from directions other than that of the imaging projection device falls on the respective segment, reduced becomes.  

Brief description of the drawings

The invention is hereinafter without limitation of the general inventions thanks based on exemplary embodiments with reference to the drawings described as an example. Show it:

Fig. 1 shows schematically a projector, a projection screen and a viewer,

FIG. 2 shows a region of the projection surface according to the invention from FIG. 1, and

Fig. 3 shows a segment of the projection of FIG. 2.

Description of an embodiment, industrial applicability

Fig. 1 shows the arrangement of a projection system according to the invention with a projector 1 and an active screen. 2 The projector 1 projects a light beam 3 onto the projection surface 2 in a manner known per se. An observer ter 4 sees the light beam reflected on the projection surface 2 , whereby an incident direction 5 and a failure direction 6 can be assigned to each point of the projection surface, along which the light beams run from the projector 1 to the projection surface 2 and from there to the viewer 4 .

According to the invention, the active projection surface 2 is divided into several segments 7 . Such a segment 7 is shown in detail in FIG. 3.

The segment 7 has, for example, a square or rectangular shape in plan view, or it can be formed with any other shape that can be assembled into a coherent surface. The segment is provided on its surface with a switchable reflection layer, which serves as a reflection element 8 and whose reflection characteristics can be specifically changed. The switchable reflection element 8 can be designed, for example, as an LCD element or an electrochromic layer, which can be controlled electrically to change the reflection.

A sensor element 9 is provided on each segment 7 . The sensor element 9 can be arranged on the surface of the segment or, as in the exemplary embodiment shown in FIG. 3, can be arranged offset to the rear with respect to the surface of the segment 7 in an aperture 10 designed as a tube. Scattered light is shielded by sensor element 9 through aperture 10 . The aperture 10 is preferably aligned in the direction of incidence 5 of the light beam arriving on the segment 7 bundle.

The sensor element 9 is a brightness sensor which emits an output signal corresponding to the detected light intensity to a control unit 11 . Each segment 7 has a corresponding control unit 11 which controls the reflection characteristic of the reflection element 8 with a control signal in accordance with the output signal of the sensor element 9 . The higher the radiance of the light projected onto the sensor element 9 from the projector 1 , the higher the reflection characteristic of the switchable reflection element 8 from the control unit 11 . The reflected radiance is thus selectively controlled by the radiance incident by the projector. If the incident radiation density is low or zero, the reflection characteristic of the reflection element 8 is kept small, so that we very efficiently avoid the reflection of scattered light that falls from a different direction than that of the projector. The individual segments 7 are each provided with their own control unit 11 and are thus independent of one another in terms of circuitry. The control unit 11 is preferably designed as an analog circuit.

The width or height extension D of each individual segment 7 is in the range from a few millimeters to a few centimeters.

The invention is not based on the exemplary embodiment explained above limits; it is also possible, for example, within the scope of the invention that Place the reflective layer an adjusting mechanism with several foldable surfaces Chen with different reflection characteristics is provided. The Stellme Mechanism can be controlled electrically by the control unit in such a way that there is a certain area in the plane of the projection area.  

For example, further modifications of the invention may include other forms of Include diaphragms and, for example, additional perforated diaphragms can be pre- will be.

Regardless of the specific design, the essential principle of the Erfin lies in the fact that for the first time a projection surface is created, the re flexion characteristic is actively adjustable in sections and the control by a projected image takes place, the sections preferably compared to Ge are as small as possible punctiform segments. This can influence of stray light in the darker areas one projected onto the screen Image can be effectively switched off. The invention thus becomes the first active projection surface created.  

Reference list

1

projector

2nd

active projection surface

3rd

Beam of light

4

Viewer

5

Direction of incidence

6

Failure direction

7

segment

8th

Reflection element with variable reflection characteristics

9

Sensor element

10th

cover

11

Control unit

Claims (11)

1. projection system with a projection surface ( 2 ) onto which an image can be projected by means of an imaging projection device ( 1 ) and on which the image appears optically in reflection,
characterized in that the projection surface ( 2 ) is divided into a plurality of reflective segments ( 7 ),
that each segment ( 7 ) is assigned a sensor element ( 9 ) and a reflection element ( 8 ) which has a variable reflection characteristic,
that the sensor element ( 9 ) detects the beam density incident on the segment ( 7 ) from the imaging projection device ( 1 ), and
that the reflection characteristic of the respective reflection element ( 8 ) is changed as a function of the detected radiance. 2. Projection system according to claim 1, characterized in that a control device ( 11 ) is provided which controls the respective reflection element ( 8 ) in accordance with the radiance detected from the direction of the projection device ( 1 ). 3. Projection system according to claim 1 or 2, characterized in that the sensor elements ( 9 ) are each provided with an aperture ( 10 ) for preventing stray light. 4. Projection system according to claim 3, characterized in that the diaphragm ( 10 ) is tubular and is aligned with its longitudinal direction to the projection device ( 1 ). 5. Projection system according to one of claims 1 to 4, characterized in that the reflection element ( 8 ) is an LCD element which can be controlled electronically to change the projection characteristic. 6. Projection system according to one of claims 1 to 4, characterized in that the reflection element ( 8 ) has a plurality of surface elements, each with different reflection characteristics, and provides an adjusting mechanism which can change the orientation of the surface elements such that one of the surface elements in each Level of the projection surface ( 2 ) is arranged. 7. Projection system according to one of claims 1 to 4, characterized in that the reflection element ( 8 ) is designed as an electrochromic layer, the reflection properties of which can be controlled electronically. 8. Projection system according to one of claims 1 to 7, characterized in that the sensor element ( 9 ) is formed out as a semiconductor sensor. 9. Projection system according to one of claims 1 to 8, characterized in that from the imaging projection device light has such a characteristic that the light against stray is light discriminatory or distinguishable. 10. Projection system according to claim 9, characterized in that the light by means of a chopper unit is a chop per frequency and / or is polarized in a preferred vibration plane.   11. Method for driving a projection system according to one of claims 1 to 10,
characterized in that the sensor elements detect the beam density of the light beams projected by the imaging projection device ( 1 ) onto the respective segments ( 7 ), and,
that the lower the radiance of the light rays coming in from the imaging projection device ( 1 ), the lower the degree of reflection of the respective segment ( 7 ) is set, and thus the reflection of scattered light which comes from other directions than that of the imaging projection device ( 1 ) falls on the respective segment ( 7 ).