DE19724139C1 - Electronic glasses - Google Patents

Description

The invention relates to electronic glasses

• a) an eyeglass frame which carries:
  • a) at least one electronic camera;
  • b) two displays, each of which can be viewed by the user via a viewing optic;
• b) image processing electronics, which the of processed image recorded by the electronic camera and an output signal for controlling the displays provides.

Glasses-like devices with which the eyesight of people to be improved are different Licher embodiment known. In particular, it can about correcting impaired eyesight greed, such as a color blindness, a twilight or Night vision or the like. Target of such devices can but also be the normal, healthy eyesight of the Increase user.

The known glasses-like devices of the beginning mentioned type, as described for example in DE-GM 92 17 643 generate the images to be viewed binocularly at a fixed, predetermined distance. The brain of the However, it is only possible for users of the the two offered images merge separately to let if the image spacing works well with the spacing the optical axes of the two eyes coincide  and also other angular errors that are due to parallax errors the eyes of the user but also on manufacturing tolerances of the displays are as small as possible.

A pair of glasses that only play from pictures used elsewhere is in the EP 0 551 781 A1. With her that is addressed above chene parallax problem solved in that by a suitable adjustment mechanism the distance between the entire imaging units is changeable. The the mechanism used for this is very complex.

The object of the present invention is therefore a electronic glasses of the type mentioned above design that with structurally simple means individual correction of the user Image distance and angular errors is possible.

This object is achieved in that

• a) at least one of the two viewing optics contains a wedge glass that
  • a) is delimited by two opposite flat surfaces which enclose an angle;
  • b) can be rotated about an axis which runs approximately perpendicular to one of the two flat surfaces and approximately parallel to the optical axis of the viewing optics.

According to the invention, one sees such a wedge glass in before at least one viewing optics, so the position of the image associated with this viewing optics by rotating the wedge glass to a certain extent  change: the center of this image moves without that there would be an axis rotation of the picture itself, on a circle. With a single such wedge glass can be a maximum of a distance difference corri yaw that ent the diameter of the circle mentioned speaks. This diameter in turn depends on the material and the geometry of the wedge glass used.

If you only use a wedge glass, certain can  Rotational positions in which the wedge angle is not exact to the right or left shows the vertical positions of the Images may be different. If this disturbs you, you can somewhat more complex embodiment of the invention used in which both viewing optics are a wedge glass contain. The correction options that way are twice the size of an off with only a single wedge glass in one Viewing optics. In this embodiment, within a by the material and the wedge angle of the Wedge glasses always have a certain catch range find, in which the vertical image positions with correct Image distance match. It can then be vertical Position of the image centers from the vertical position of the optical axis deviate; however, this can be done by appropriate setting of the heights of the viewing optics on Nose piece can be compensated.

The holder is expediently at least one Wedge glasses designed to hold a correction lens. If the user of the electronic glasses is defective, Corresponding correction glasses can be placed in this holder be accommodated. Another correction of the Ametropia, e.g. B. with the help of contact lenses then dispensable what the use of electronic Makes glasses very comfortable.

It has proven to be advantageous if each viewing optic comprises:

• a) a semi-transparent mirror, on which the by the Display coming light rays at an angle impact from about 45 °;
• b) a concave mirror on which the semitranspa  pensions reflect reflected rays and this way through the semi-transparent The mirror reflects that the display on the retina of the user is mapped.

An embodiment of the invention is as follows explained in more detail with reference to the drawing; show it

Fig. 1 shows schematically the physical design of an electronic glasses according to the invention;

Fig. 2 shows schematically the beam path in the viewing optics of one of the two displays of the electronic glasses of Fig. 1;

FIG. 3 shows the beam path by a wedge glass;

Fig. 4 positions as the user of the electronic glasses of Fig. 1 and 2 perceives on both eyes at different rotational positions of the wedge glasses.

As can be seen from FIG. 1, the electronic glasses consist of two main components, namely a glasses part 1 and a pocket part 2 , which are connected to one another via an electrical cable 3 .

The eyeglass part 1 comprises a glasses frame 4 , which is usually to be carried out, on which at least one electronic camera, for. B. CCD camera, 5 and for each eye an electronic display 8 with the associated viewing optics, which will be discussed below, are attached. The image recorded by the electronic camera 5 is processed in a known manner (not explained in more detail here) by image processing electronics and displayed on the displays 8 in such a way that the user can view the electronically processed image binocularly. The image processing electronics can partially be provided directly in the glasses part 1 ; insofar as larger and heavy components are used for this, they are advantageously accommodated in the pocket part 2 .

The pocket part 2 also contains a battery 9 and a socket 10 for peripheral devices. It can be worn on the shoulder of the user by means of a strap 11 .

FIG. 2 shows schematically from above the beam path in the viewing optics of one of the two displays 8 , which is used in the glasses of FIG. 1. With the aid of these viewing optics, the image displayed on the display 8 is displayed on the retina of the user in a manner known per se in such a way that the user can view the display 8 with the eye ("infinitely") accommodated for distant vision. In detail, the beam path (only the optical axes are shown in the drawing) is as follows:

The light rays emanating from the display ( 8 ) (for example an LCD display) fall at an angle of approximately 45 ° onto a semitransparent mirror 20 and are directed by this onto a concave mirror 21 . The concave mirror 21 reflects the rays back, so that they (partially) pass through the semi-transparent mirror 20 in the direction of the user's eye 22 . The imaging properties of the concave mirror 21 are selected so that the display 8 appears to be infinite for the user.

So far, the viewing optics are known from the prior art. In Fig. 2, the light coming from concave mirror 21 passes through the semi-transparent mirror 20 through a wedge glass 23 and a correction lens 24 , which are rotatably mounted in a holder 25 about the optical axis of the viewing optics.

The purpose of the wedge glass 23 is to compensate for angular errors which can be attributed to parallax errors in the eyes of the user or different eye distances and manufacturing tolerances in a manner which is now described with reference to FIG. 3.

In Fig. 3 a wedge glass 23 is shown schematically. It comprises two opposite, flat surfaces 30 , 31 , which are positioned at an angle κ against each other. The material from which the wedge glass 23 is made has the refractive index n ₂ ; the surrounding medium has a refractive index n ₁ . In the application in the viewing optics of Fig. 2, the ambient medium is air; n ₁ is therefore approximately 1.

Fig. 3 shows the passage of a light beam through the wedge glass 23 , which follows the usual laws of refraction. That is, the α at an angle α ₁ = _E to the first planar surface 30 of the wedge lens 23 incident light beam is refracted towards the perpendicular E; it continues at an angle α ₂ within the medium of the wedge glass 23 . On the second flat surface 31 of the wedge glass 23 , the solder A is tilted relative to the solder E on the incident side by the angle κ. Again according to the laws of refraction, the light beam emerging from the wedge glass 23 is broken away from this solder A at an angle β ₁ . Based on the solder E on the incident side, the emerging light beam has a deflection angle β _A , as can be seen in detail in FIG. 3.

If the wedge glass 23 is now rotated either around the solder E on the incident side or around the solder A on the incident side by means of the holder 25 from FIG. 2, the incident beam migrates approximately on a conical surface. The center of the image, which is perceived by the viewer, moves on a circle, but without the axis itself rotating.

The mode of operation of such wedge glasses 23 in electronic glasses, in which the viewing optics of both displays 8 are equipped with such a wedge glass 23 , can be seen in FIG. 4. In the partial figures 4a to 4c, four possible positions of the image are shown for the left and the right eye, which each result from the rotation of the associated wedge glass 23 by 90 °. The one of these four positions, which in the partial figure under consideration is currently occupied by a corresponding position of the wedge glass 23 , is shown in bright color, while the image positions which are not realized in the specific case are shown hatched.

In the partial figure 4a, the wedge glasses 23 of both viewing optics are set in the same way so that the respectively observed image is shifted upwards relative to that position that would be obtained without the wedge glass 23 . However, the lateral distance between the images perceived by both eyes is unchanged compared to optics without wedge glasses 23 . This change in the "basic height" of the viewed images caused by the wedge glasses 23 can be compensated for by a corresponding displacement of the nose piece of the spectacle frame 4 .

In FIG. 4b that position of the images seen by the user is shown which arises when the two wedge glasses 23 in the two viewing optics are each rotated through 90 ° in the opposite sense. It can be seen that the lateral distance between the two images has now become significantly larger, namely precisely by the diameter of the circles on which the center of the images moves when the wedge glasses 23 are rotated. This is the maximum distance of the images that can be achieved with the arrangement described here.

From this position, by rotating the two wedge glasses 23 by 180 °, a position would be reached in which the images seen by the user approached each other at the smallest distance. This position is not specifically shown in Fig. 4; the situation is easily imaginable.

While the viewing height of the two images in the two viewing optics is the same at the rotational positions of the wedge glasses 23 in FIGS. A and b, the viewing height of the two images is different in FIG. 4c. Here, only the wedge glass 23 located in the viewing optics assigned to the right eye of the user was rotated by 90 ° in one direction of rotation, while the left wedge glass 23 has not left the starting position of FIG. 4a.

From the above description of Fig. 4 follows, of course, that in practice not only the four positions of the two wedge glasses 23 used as examples, but also that any intermediate position is possible. This allows an optimal adjustment of the image distance to the individual circumstances of the individual case, both on the part of the user and on the part of the electronic glasses themselves, achieve.

Correction glasses 24 , as shown in FIG. 2, are only used if this is necessary to correct myopia, hyperopia or astgmatism. This correction would otherwise have to be done by the user of the glasses wearing contact lenses.

In the exemplary embodiment described above, it was assumed that the viewing optics for both displays 8 each contain a wedge glass 23 . If you omit some of the setting options, it may also suffice in individual cases to accommodate such a wedge lens 23 in only one of the two viewing optics.

Claims (4)

1. Electronic glasses with

• a) a spectacle frame that wears
  • a) at least one electronic camera;
  • b) two displays, each of which can be viewed through a viewing optics by the user binocularly;
• b) image processing electronics, which process the image recorded by the electronic camera and provide an output signal for controlling the displays,

characterized in that

• a) at least one of the two viewing optics contains a wedge glass ( 23 ) that
  • a) is delimited by two opposite flat surfaces ( 30 , 31 ) which enclose an angle (κ);
  • b) is rotatably mounted about an axis (A) which runs approximately perpendicular to one of the two flat surfaces ( 30 , 31 ) and approximately parallel to the optical axis of the viewing optics.

2. Electronic glasses according to claim 1, characterized in that both viewing optics contain a wedge glass ( 23 ). 3. Electronic glasses according to claim 1 or 2, characterized in that the holder ( 25 ) at least one wedge glass ( 23 ) is designed to receive a correction lens ( 24 ). 4. Electronic glasses according to one of the preceding claims, characterized in that each viewing optics comprises:

• a) a semi-transparent mirror ( 20 ), on which the light rays coming from the display ( 8 ) strike at an angle of approximately 45 °;
• b) a concave mirror (21) on which the light reflected by the semi-transparent mirror (20) beams are incident, and that the display (8) is imaged on the retina of the user of these rays reflects so by the semi-transparent mirror (20).