DE10127366A1 - Laser projection of a wide angle image onto the surface of a human eye - Google Patents

Abstract

The observers eye is represented by an ideal lens (8) with an image plane of the eye surface(9). The image modulated light (1) falls a lens(2) and is deflected by a mirror (6) onto a second mirror (7) in front of an elliptic reflector(4). The mirror position is dependent upon the wavelength of the optical beam. This provides an extremely wide angle field of vision.

Description

The invention relates to an optical arrangement and a method for the projection of single or multi-colored video images onto the retina of the human eye with the aid of a light beam modulated in brightness and its color (for example a laser beam mixture), but which mirror one or more electrically controlled deflections (Mirror scanner) is guided two-dimensionally over the retina for sequential sharp imaging of the pixels. Depending on the application, either only the video image (application: video glasses) is projected onto the retina, or the video image is additionally overlaid with the image of the field of vision of the eye through the outer ellipsoid ( 4 ) (application: pilot glasses).

Various optical arrangements for solving this problem are known in the prior art, e.g. B .:

• 1. "Helmet-Mounted Displays and Sights", Mordekhai Velger, Artech House, Boston / London, 1998
• 2. "The TV in the glasses", Electronics p.18,20,1999
• 3. US-Pat.Nr. 6,140,979, Microvision Inc. 10/31/2000

All previous projection systems are based on due to the optical aberrations and the arrangements these systems often only have a small maximum video image angle between 20 ° -40 ° reached, or the image sharpness is not satisfactory (see under 2.).

3. is in contrast to this patent application an optical systems mentioned that is a pair there is a curved and partially transparent mirror, whereby the eye must look through both partial areas without detailed description of the type of laser beam and  Type of curved surfaces that make up the functional capability of the system.

It was therefore the aim of this invention to be an optical one System to create with a video field up to maximum approx. 0 °, overlaid with an extreme wide-angle view field of up to approx. 120 ° z. B. for use in Helmet display systems for helicopter pilots.

This object is achieved by the measures laid down in the characterizing part of claim 1. In the subclaims, advantageous refinements are specified in the description below and the invention will be illustrated by a few embodiments and the associated optical structure and its optical path in the drawings Fig. 1 and Fig. Shown schematically. 2 A single or multi-colored parallel light beam (e.g. laser beam mixture) is assumed, the color components of which are modulated in their brightness by the serial pixel data of a video signal. Furthermore, an electronic control unit is required, which generates the necessary control signals from the line and image sychronis signals or other data for the coordinates of the pixels in order to electrically control the gimbal-mounted two-axis deflection mirror (mirror scanner) ( 7 ), so that the light beam for each pixel of the video signal is deflected by the deflecting mirror ( 7 ) by the required azimuth and elevation angle, so that the pixel on the retina ( 9 ) of the observer's eye is imaged at the desired location in the projected video image.

The observer eye is replaced in FIG. 1 and FIG. 2 by an ideal eye, with the ideal thin lens ( 8 ) and the associated image plane, ie the retina ( 9 ). The presupposed modulated light beam, represented by two marginal beams and a central beam, is fed in Fig. 1 and Fig. 2 at the coupling point ( 1 ) of a single or multi-lens arrangement ( 2 ) which beam the parallel light beam into a divergent light with the desired beam cross-section is transformed and fed via a deflecting mirror ( 6 ) to the two-axis deflecting mirror ( 7 ). In Fig. 1 and Fig. 2, the deflecting mirror ( 7 ) is drawn simultaneously in five different deflection angle positions with the associated reflected beams. Each divergent beam bundle reflected by the deflecting mirror ( 7 ) for an angular position is assigned a virtual beam intersection behind the deflecting mirror ( 7 ). These virtual intersections of all angular positions of the deflecting mirror ( 7 ) lie on a spherical surface which represents the virtual object which must be displayed as a video image on the retina ( 9 ).

To curvature the field of view, the divergent light bundles after the deflecting mirror ( 7 ) pass through the single or multi-lens lens group ( 3 ) and then enter a reflection channel which consists of the inner mirrored outer ellipsoid ( 4 ) and an outer mirrored inner ellipsoid ( 5 ). The deflection mirror ( 7 ) is located in or near the left focal point of the outer ellipsoid ( 5 ). The exact position of the deflecting mirror ( 7 ) depends on the optical path length of the light rays through the lens system ( 3 ).

The reflected beam bundle belonging to an angular position of the deflecting mirror ( 7 ) passes through m = 1, 2, 3, 4,. , , Reflections on the outer ellipsoid ( 4 ) and m-1 reflections on the inner ellipsoid ( 5 ). In Fig. 1, the case with m = 2 and is shown in Fig. 2 shown is the case with m = 3. In Fig. 1 and Fig. 2, the centers of the two ellipsoids ( 4 ) and ( 5 ) and the directions of their major and minor major axes coincide. In or near the right focal point of the outer ellipsoid ( 4 ), the light beams intersect in the exit pupil of the system, where the pupil and the lens ( 8 ) of the observer's eye are arranged. The bundle of rays that belongs to a deflection angle position of the deflection mirror ( 7 ) is parallel before entering the eye lens ( 8 ) and is thus formed in a punctiform manner by the eye lens ( 8 ) on the retina ( 9 ).

For correcting ametropia of the observer's eye consisting of lens ( 8 ) and retina ( 9 ), correction optics can be arranged in front of the eye lens ( 8 ) to produce low beam convergence or beam divergence. If the video image on the retina is to be overlaid with the image of the visual field of the eye (e.g. application: aviator glasses), the outer ellipsoid ( 4 ) is only partially reflective in an area between points P1 and P2. If movement of the observer's eye (rotation of the optical axis of the eye) is to be permitted when observing the projected video image, then it is advisable to provide an image sensor ( 10 ) or a multi-segment light detector with an imaging lens for observing the surface of the eye in the area of the eye lens ( 8 ). The position of the pupil of the observer's eye can then be determined from the sensor signals and this position can be tracked. From this, control signals can be obtained for a two-dimensional linear drive system, which comprises the entire optical arrangement consisting of the components ( 1 ), ( 2 ), ( 6 ), ( 7 ), ( 3 ), ( 4 ), ( 5 ), ( 10 ) so ver pushes that the exit pupil of the system in or near the right focal point of the outer ellipsoid ( 4 ) tracks the pupil movement of the observer eye.

This shift of the system is typically carried out perpendicular to the direction of the light beam at the coupling point ( 1 ). If the cross section of the fixed modulated light beam offered there is sufficiently large compared to the cross section of the light beam received at the coupling point ( 1 ), then the coupling in of the modulated light beam is possible without any problems even when the system is shifted.

Using the example of FIG. 1, the image diagonal for the observer eye reaches an image field angle of approximately 120 ° and a video field angle of approximately 60 °.

Claims (5)

1. Optical arrangement and method for the projection of electronic image data (e.g. one or more colored video images) onto the retina of the eye, characterized in that let a single or multi-colored light beam (e.g. laser beam mixture) that is in brightness of its color components for each individual sequentially projected pixel is modulated by the content of a video signal, from an electrically controllable biaxial deflection mirror (mirror scanner) ( 7 ) arranged in or near the first focal point of an outer ellipsoid ( 4 ) onto the one for projecting each individual pixel Necessary azimuth and elevation angle is deflected, then a single-lens or multi-lens system ( 3 ) for correcting the image field curvature error on the retina ( 9 ) passes through and then diverges into a mirror channel consisting of the inner mirrored outer ellipsoid ( 4 ) and the outside mirrored inner ellipsoid ( 5 ) and after m = 1, 2, 3, 4,. , , Reflections on the outer ellipsoid ( 4 ) and after m-1 reflections on the inner ellipsoid ( 5 ) near the second focal point of the outer ellipsoid ( 4 ) meets the eye lens ( 8 ) and is focused on the retina ( 9 ) as a pixel. 2. Arrangement according to claim 1, characterized in that the two ellipsoids ( 4 ) and ( 5 ) have a common center GE. 3. Arrangement according to one of claims 1 or 2, characterized in that the optical system contains a spatially resolving density detector ( 10 ) (image sensor or multiple segment light detector) with imaging optics for observing the eye movement, so that the position of the eye pupil can be determined from the detector signals control signals for servomotors can be generated, which the entire optical projection system, consisting of the components ( 1 ), ( 2 ), ( 6 ), ( 7 ), ( 3 ), ( 4 ), ( 5 ), ( 10 ) move so that the intersection of all light rays in the eye lens ( 8 ) tracks the movement of the eye pupil. 4. Arrangement according to one of claims 1 to 3, characterized in that the outer ellipsoid ( 4 ) in the area of a partial area between the points P1 and P2 is a partially transparent mirror, for superimposing the projected video image on the retina with the image field of the eye, observed through the outer ellipsoid ( 4 ). 5. Arrangement according to one of claims 1 to 4, characterized in that the light rays pass before entering the eye lens ( 8 ) a single or multi-lens optical system with a fixed or variable focal length, which serves to correct possible ametropia of the eye, or it enables the viewer to adjust the distance between the eye and the virtual object of the image projection onto the retina between finite and infinite distance.