DE19933397A1 - System for protection of eyes against glare has a screen of variable transparency controlled by a computer according to data from units to identify the location of the light source and the eyes and line of sight - Google Patents

Abstract

The system for the protection of eyes against radiation and light glare has a location unit (3) which gives a continuous and dynamic identification of the position of at least one light source (11). A further unit (4) determines the position of the eyes (12) and/or the direction of vision. A transparent and flat screen carrier (5) is in front of the eyes (12), with a transparency which is varied locally and at times by screen spots (9) of a lower transparency which absorb or reflect light. A control unit (2) computes the geometric coordinate data for the lines (13) of the light from the light source (11) and the position and direction of the line of sight at the eyes (12), for the intersection (14) of the line of sight with the angle of light through the screen, to set the level of screen transparency accordingly.

Description

The invention relates to an eye protection device against one Radiation source incident radiation, such as. B. electromagnetic Radiation of all kinds or particle radiation. In particular, the Invention on an anti-glare device for use in vehicles, Motorcycle helmets, glasses and. the like

The background of the invention is most obvious at the kon Cretan example of road traffic. There is still largely there unresolved problem is the dazzling of oncoming traffic when driving at night. So far, the glare has been tried to solve this problem through suitable manipulations at the glare source, e.g. B. to the To reduce headlights of a motor vehicle. For example se known to integrate a light sensor in vehicles that counter upcoming vehicles recorded and the own headlights at Gegenver switches from high beam to low beam. Although this brings a protective effect for the other road user, a self-glare by oncoming vehicles that have such automatic Ab Do not have glare devices and their drivers forget the stopping down sen, but is not prevented. In addition, there are so far still no effective anti-glare protection against highly reflected light like it For example, on wet asphalt, even with the dipped headlights properly adjusted position of oncoming traffic occurs.

Effective eye protection not only plays in the field of traffic engineering plays a role. For example, also in the area of the Ar occupational safety, for example when dealing with welding machines or laser equipment  the eyes are to be protected by suitable measures. Here is the Problem that z. B. Laser goggles or welding visors either have an extremely reduced transmission and are therefore recognizable objects outside of the radiation source are often extremely difficult ren, or are wavelength sensitive, d. H. for example only for one spe Target type of laser source develop a protective effect at all.

Based on the problems outlined, the invention lies on based on an eye protection device against radiation source of incident radiation and in particular an anti-glare device specify the variable at the position of the at least one beam adjustment source and the eyes and a selective dimming of the allows the eyes directed glare.

To solve this problem, an eye protection device is provided according to the invention

• - A location device for ongoing dynamic detection of Position of the at least one radiation source,
• - An eye position detection device for determining the position tion and / or the line of sight of the eyes to be protected,
• - A transparent, flat panel support in front of the ones to be protected Eyes on which the beam is variable at least in time and place lung absorbing or reflecting lens flare with preferably two dynamically variable reduced transparency can be generated, and
• - One with the location and eye position detection device and the computing and control device coupled to the panel support, the from the position detected by the locating device Radiation source and be continuously from the detection device  the position of the eyes to be protected matched the connection coordinates naten between eyes and source of radiation and their penetration bog dinates continuously calculated by the aperture support and in the range of puncture coordinates calculated in each case by corresponding An Control of the aperture holder or the lens flare generated.

Due to this design of the eye protection device, a dy Named anti-glare protection, which is in "real time" in its position and training the lens flare to the relative to the or Adjusting the eye-moving source of glare. A corresponding one will be used A lens flare is only generated if there is a source of glare. The Formation of the aperture support and the apertures to be produced thereon spots can be adapted to the quality of the radiation sources. So is for a protective device, its panel support in a vehicle windshield or a visor of a motorcycle helmet is integrated, a transparent liquid crystal matrix arrangement for producing an or also suitable for several lens flares that counter the headlights of one hide the coming vehicle. By continuously determining the Position of the glare source by the locating device and the position or direction of view of the eyes to be protected with the help of the eye position ons detection device can from the computing and control device continuously and in real time, for example, the piercing point of the connective straight line between the eyes and the respective radiation source calculated by the aperture holder and there created the lens flare the. If the shape and / or size of the radiation source is also detected, this allows the lens flare to spread on the lens holder be adapted to it. In this case, as connection and Puncture coordinates not only the straight line and  Penetration point between eyes and the respective radiation source, son who practically the envelope or the "connecting body" between the from the eyes and the radiation source or sources, dyna mixed changing local areas calculated. Regarding the capture of the Glare quality is based on, for example, the intensity of the radiation source (s) to be dimmed before the background brightness value is.

Incidentally, it is pointed out that under "glare" not only visible light with high intensity, but generally radiation quality are understood to be uncomfortable or harmful to the person are protective eyes. Furthermore, the device according to the invention not only directly record radiation sources as such, but also fig of such radiation sources on reflective surfaces such. B. Reflections of oncoming traffic headlights on wet asphalt.

Finally, according to a preferred embodiment of the invention the glare quality, d. H. for example the difference in intensity between the source of glare and the ambient brightness, this can be necessary The transparency dimension of the lens flare is dynamically changed and displayed be fit.

Advantageous developments of the invention result from the Unteran say and the following description, in which an execution game of the subject of the invention with reference to the accompanying drawings is explained in more detail. Show it:  

Fig. 1 is a block diagram of the components of an eye protection device, and

FIG. 2 shows a highly schematic top view of a motor vehicle with an eye protection device according to FIG. 1.

The eye protection device shown in the figures is designated as a whole by the reference number 1 . It has a central computing and control device 2 which works with microprocessor support. Further components are a locating device 3 based on a camera system with at least one camera comprising a CCD sensor, an eye position detection device 4 , which is formed by a known, laser-based eye tracking system, and a so-called aperture support 5 , which is formed in the exemplary embodiment shown in FIG. 2 by a transparent liquid crystal matrix arrangement which is integrated in the windshield 6 of the motor vehicle 7 . The matrix arrangement covers the entire surface of the windshield 6 and is divided into individual matrix-shaped liquid crystal elements with a size of a few tenths of a mm ² up to the square centimeter range. As usual with LCD displays, individual matrix elements can be controlled via a driver stage 8 and the transmission behavior of the matrix arrangement in individual matrix elements can be changed in a targeted manner. It can therefore be generated temporally and spatially variable in defined areas of the surface of the aperture support 5 dark lens patches 9 , in which the windshield 6 then becomes less transparent to non-transparent.

The operation of the anti-glare device can now be explained with reference to FIG. 2:
The CCD sensor camera of the locating device 3 continuously detects the area outside the motor vehicle lying in the field of vision of the driver 10 . As soon as a glare source in the form of a headlight 11 of an oncoming vehicle is detected by the locating device 3 , the corresponding coordinate data of the changing headlight position and data that represent the radiation intensity of the headlights are continuously passed to the central computing and control device.

Simultaneously, the positions of the eyes 12 of the driver 10 are detected by the eye position detection device 4 . The corresponding coordinate data are also forwarded to the central computing and control device 2 . In addition, data about the driver's glare sensitivity and adaptation speed, which are also stored in the central computing and control device 2, can also be included in the computing process.

The computing and control unit continuously calculates the spatial coordinates of the straight line 13 between the eyes 12 and the headlights 11 from the coordinate data of the headlights 11 and the eyes 12 . From these data, which are related to the coordinate system "motor vehicle", the coordinates of the imaginary penetration points of the straight line 13 through the diaphragm support 5 in the windshield 6 can also be calculated. The computing and control device 2 is designed in such a way that all radiation quality coordinate detection and further processing processes take place in real time, the lens flares 9 on the penetration points 14 are thus dynamically adapted to the changing positions of oncoming vehicle and own motor vehicle 7 .

On the basis of the calculated penetration points 14 , the computing and control device 2 controls the liquid crystal matrix arrangement via the driver stage 8 so that the corresponding LCD matrix elements for forming the lens flares 9 are darkened around the penetration points 14 . Since the CCD sensor camera of the locating device 3 is designed such that the shape and size of the headlights 11 is additionally detected, the lens flares 9 are also correspondingly designed in shape and size.

Finally, a brightness measuring device 15 is provided in the eye protection device 1 , which determines the ambient brightness. Based on the corresponding measurement data, which are also given to the central computing and control device 2 , including the data from the locating device and the stored data on glare sensitivity and adaptation speed of the driver, the transparency factor of the lens flare 9 that is necessary to achieve a sufficient glare protection effect can be determined and the aperture support 5 can be controlled accordingly. In practice, this means that in an oncoming vehicle traveling in the daytime with light that has practically no dazzling effect on the driver, no lens flare is generated. At dusk, when only a slight glare is to be expected, the liquid crystal matrix arrangement is activated in such a way that the transmission is only slightly reduced in the area of the lens flare. At night, the lens flare transmission can be regulated down to practically zero.

As can be seen from the above, the eye protection device according to the invention darkens the exact area of the windshield behind which the headlights of an oncoming vehicle are located. To this extent, the driver 10 is effectively protected against dazzling oncoming traffic. Nevertheless, practically the entire area of the windshield remains unimpaired in its transmission, whereby the night vision properties through the windshield practically do not deteriorate, but are even improved considerably.

As a further anti-glare measure, which can be achieved with the above object of the invention, can be provided in connection with the brightness measuring device 15 that at a very high level of brightness, such as. B. when driving on coastal roads under sunlight, the aperture support 5 is dimmed on its entire surface by reducing its degree of transparency.

As is not shown as a specific exemplary embodiment, an eye protection device according to the invention can also be used in a motorcycle hitch be set, in which case the aperture support is integrated into the visor. The use of the device in protective glasses, such as. B. one Laser safety glasses, or possible with a welding visor. Not least the panel holder can also be integrated into an independent screen the one that can be positioned in the room in front of the person to be protected. As in all other embodiments of the aperture support can optically ak tive layer or layer in the volume of the flat carrier or on the same Surface attached.

Claims (11)

1. Eye protection device against radiation from at least one radiation source, in particular glare protection device for use in vehicles, motorcycle helmets, glasses and the like

• - a locating device ( 3 ) for the continuous dynamic detection of the position of the at least one radiation source ( 11 ),
• - an eye position detection device ( 4 ) for determining the position and / or the viewing direction of the eyes to be protected ( 12 ),
• - a transparent, flat diaphragm support ( 5 ) in front of the eyes ( 12 ) to be protected, on which at least one radiation-absorbing or reflecting diaphragm spot ( 9 ) with reduced transparency can be generated, variable in time and location, and
• - One with the location and eye position detection device ( 3 , 4 ) and the diaphragm support ( 5 ) coupled computing and control device ( 2 ), which is continuously detected by the location device ( 3 ) position of the at least one radiation source ( 11 ) and the position of the eyes ( 12 ) determined continuously by the detection device ( 4 ), the geometric connection coordinates ( 13 ) between eyes ( 12 ) and the at least one radiation source ( 11 ) and their penetration coordinates ( 14 ) through the aperture support ( 5 ) continuously calculated and generated in the area of the calculated collision coordinates ( 14 ) by appropriate activation of the aperture holder ( 5 ) the lens flare (s) ( 9 ).

2. Protection device according to claim 1, characterized in that the locating device ( 3 ) is designed such that in addition shape, glare quality and / or size of the radiation source ( 11 ) can be detected. 3. Protection device according to claim 1 or 2, characterized in that the locating device ( 3 ) is formed by a camera system. 4. Protection device according to claim 3, characterized in that the camera system comprises a CCD sensor. 5. Protection device according to one of claims 1 to 4, characterized in that the eye position detection device ( 4 ) is formed by an eye tracking system with which the position of the eyes ( 12 ) themselves or at least the head position of the correspond Person ( 10 ) can be detected. 6. Protection device according to one of claims 1 to 5, characterized in that the aperture support ( 5 ) has a transparent liquid crystal stall matrix arrangement in which the computing and control device ( 2 ) controlled in defined surface areas of the aperture holder ( 5 ) whose transparency can be removed to achieve the lens flare ( 9 ). 7. Protection device according to one of claims 1 to 6, characterized in that a brightness measuring device ( 15 ) for determining the ambient brightness is provided, the computing and control device ( 2 ) from the data of the locating device ( 3 ) and the brightness measuring device ( 1 S) determines the degree of transparency of the lens flare ( 9 ) necessary to achieve a glare protection effect and controls the aperture support ( 5 ) accordingly. 8. Protection device according to one of claims 1 to 7, characterized in that the panel support ( 5 ) in a vehicle windshield disc ( 6 ) or a visor is integrated. 9. Protection device according to one of claims 1 to 7, characterized in that the diaphragm carrier ( 5 ) is integrated into glasses, in particular safety glasses. 10. Protection device according to one of claims 1 to 7, characterized in that the diaphragm support ( 5 ) is integrated into a screen that can be positioned in front of the person to be protected ( 10 ). 11. Protection device according to one of claims 1 to 7, characterized in that the diaphragm support ( 5 ) is dimmable on its entire surface.