KR20160039958A - Hologram 3 dimension eye-glasses - Google Patents

Abstract

The present invention relates to a 3 Dimensional (3D) hologram eyeglasses including: a support (10) supporting a lens or a protective mirror (20) placed at the front side of eyes (210); the lens or the protective mirror (20) attached to the support (10) and installed at the front side of the eyes (210); a coherent light projector (30) installed on a nose pad portion (11) of the support (10) and forming a coherent light hologram (111) at the front side of the lens or the protective mirror (20); and a reference light projector (40) installed at the front side of a temple tip support (12) of the support (10) and forming a reference light hologram (112) at the front side of the lens or the protective mirror (20). The 3D hologram glasses form a lens hologram with a power function by attaching a hologram projector on a chassis worn by the eyes and projecting a lens hologram at the front side of the lens from the hologram project, thereby preventing the glasses from inclining to one side due to a phenomenon which one lens is thicker and heavier than the lens because of a remarkable vision difference between two eyes. Further, the 3D hologram glasses enhance beauty and convenience as well as provide a lens helpful to correct vision of a wearer.

Description

[0001] HOLOGRAM 3 DIMENSION EYE-GLASSES [0002]

The present invention relates to hologram three-dimensional glasses, and more specifically, a hologram projector is inserted into an eyeglass frame worn on an eye, and a hologram is irradiated onto the entire surface of the lens in a hologram projector to form a lens hologram having a dioptric function. The present invention relates to a hologram three-dimensional (3D) eyeglass that can improve aesthetics and convenience of a spectacle as well as form a lens for assistance.

Three-dimensional (3D) image reconstruction techniques include stereooscopy, holography, and an integrated imaging method. In the holographic method, when the light source is illuminated to the holography, the observer observes the holographic image while observing the stereoscopic image of the virtual image while keeping a certain distance from the front of the holography.

The principle of the hologram is to divide the light rays from the laser into two, direct one light beam directly on the screen, and shine the other light beam on the object. At this time, the light that directly illuminates the screen is referred to as a reference wave, and the ray that illuminates an object is referred to as an object wave.

Since the object wave is a ray reflected from each surface of an object, the phase difference varies depending on the distance from the object surface to the screen. At this time, the undeflected reference wave interferes with the object wave, and the generated interference fringe is stored on the screen. The film in which such interference fringes are stored is called a hologram.

The hologram processing generates the hologram pattern by receiving the depth data, and then outputs the hologram data by using the hologram reconstruction tool.

Korean Patent Registration No. 10-1090787 calculates the high frequency component of the input data by changing the depth of the non-continuous pixel according to the boundary change of the input depth data, and calculates the absolute value of the high frequency component to generate depth change information, The average envelope information including the change information about the depth of the discontinuous pixel of the input depth data is calculated along the trajectory of the information and the high frequency component is added to the boundary according to the depth variation of the input depth data based on the average envelope information Depth map conversion information that represents the information, adds the input depth data and the depth map conversion information to calculate the final depth data, and generates a computer generated hologram (CGH) output data using the final depth data. A hologram processing apparatus and method using conversion "has been proposed.

Korean Patent Publication No. 10-2006-0048850 discloses a hologram device that automatically corrects the displacement of a pixel level of an optical modulator and an image sensor, a method of positioning a spatial light modulator and an image pickup device, Material "has been proposed.

Korean Patent Laid-Open No. 10-2005-0066947 discloses a three-dimensional stereoscopic image displayed by a funnel method, in which a three-dimensional stereoscopic image displayed by a polarization method can be observed regardless of the movement of an observer such as a head circumference, Quot; a three-dimensional image viewing apparatus using a rotating polarizer "that can always keep the polarization direction (polarization vector) of the polarized light in the same direction is proposed as shown in Fig.

Fig. 1 shows an exemplary configuration of polarizing glasses to which a three-dimensional image viewing apparatus (polarizing lens) according to the related art is applied.

As shown in Fig. 1, the polarized glasses have left / right polarized lenses 1 and 2 for outputting polarized light of a specific polarization direction (polarization vector) incident from the outside to left and right eyes of an observer, And a spectacle frame 3 for supporting the polarizing lenses 1 and 2.

This conventional technique does not limit the motion of the observer when the polarizing glasses are worn on the three-dimensional stereoscopic image displayed by the polarizing method, but also to the movement of the observer such as the rotation and movement of the head, However, since the visual acuity of both eyes is significantly different, when both lenses of glasses have different dioptric power, the lens of one eye is thicker and heavier than the lens of the other eye, and the problem of tilting to one side is solved can not do.

Korean Patent Registration No. 10-1090787 (registered, December 1, 2011) Korean Patent Publication No. 10-2006-0048850 (published May 18, 2006). Korean Patent Publication No. 10-2005-0066947 (published Jun. 30, 2005)

SUMMARY OF THE INVENTION The present invention has been made in order to solve the conventional problems as described above, and it is an object of the present invention to provide an eyeglasses lens system, in which the visual acuity of both eyes is remarkably different, A hologram three-dimensional spectacle lens which is thicker and heavier than a lens and which can solve the problem of tilting to one side.

It is another object of the present invention to provide a hologram lens hologram having a hologram function by inserting a projection on an eyeglass frame and irradiating the hologram on the entire surface of the lens in the projection, thereby not only helping the wearer correct the visual acuity but also improving the aesthetics and convenience Dimensional holographic three-dimensional glasses.

In order to achieve the above object, the hologram 3D glasses according to the present invention include: a lens positioned on the front of the eye; A lens or protective liner attached to the support and installed on the front of the eye; An interference light projector provided on the support and forming an interference optical hologram on the entire surface of the lens or the protective mirror; And a reference light projector mounted on the opposite side of the interference light projector with respect to the lens or the protective lens to form a reference light hologram on the front surface of the lens or the protective mirror.

According to an embodiment of the present invention, the support member may be worn on the wearer's eye to support the nose of the wearer's nose so as to support the lens or the protective eyelash, And the like.

According to an embodiment of the present invention, the support base is a left and right nose pad having a silicone resin material adhered to the nose of the wearer and coated with an adhesive.

According to an embodiment of the present invention, the support is made to be worn on both eyes of the wearer and two lenses or protective goggles are provided on the support made to be worn on both eyes, and the goggle support is placed over the left ear and right ear A hologram is formed on the entire surface of a lens or a protective lens which is worn on both eyes by adding the interference optical projector and the reference light projector.

According to an embodiment of the present invention, the interference light projector irradiates the interference light hologram, and the reference light projector irradiates the reference light hologram, and the interference hologram and the reference light hologram are combined to form a power lens hologram, Of the hologram.

According to an embodiment of the present invention, the interference optical hologram projector may be configured such that an interference optical computer generated hologram (CGH) data of the lens obtained by a mathematical operation expressing a computer generated hologram (CGH) A laser generating unit for forming an interference optical lens hologram on the entire surface of the lens or the protective glass 20; A graphic processing unit for receiving the interference optical computer generated hologram (CGH) data of the lens in the interference light hologram storage unit to process the hologram data into a three-dimensional hologram and output it to the laser generation unit; The computer-generated hologram (CGH) data of the lens obtained by a mathematical operation is stored in an equation representing a computer generated hologram (CGH) of the lens, and the interference optical computer generated hologram (CGH) An interference light hologram storage unit for outputting the interference light hologram to the processing unit; Controls the interference light hologram storage unit to output the interference light hologram data to the graphic processor, and controls the graphic controller to process the interference light hologram data to output the interference light hologram data, A projector control unit for controlling the laser generating unit to form an interference optical lens hologram; And an optic nerve sensor for sensing an electrical signal generated by the optic nerve of the wearer and inputting the electrical signal to the projector control unit so that the projector control unit forms a lens hologram corresponding to the wearer's vision on the front surface of the lens or the protective screen, The projector may include a reference light hologram storage unit instead of the interference light hologram storage unit.

According to an embodiment of the present invention, the graphic processing unit inputs the interference light or the reference light computer generated hologram data obtained through a mathematical operation to an equation representing a computer generated hologram of the lens in the interference light hologram storage unit or the reference light hologram storage unit Dimensional hologram in accordance with the control of the projector control unit, and processes the computer generated holograms CGH defined mathematically in parallel to output to the laser generation unit.

According to an embodiment of the present invention, the interference light hologram storage unit and the reference light hologram storage unit may store computer generated hologram (CGH) data of a lens having various dioptric powers, and if necessary, And outputs generated hologram (CGH) data.

According to an embodiment of the present invention, a GPS receiver and a wireless communication unit are added to the interference light projector and the reference light projector so that the geographical information data is superimposed on the lens hologram and the wearer receives the augmented reality service through the lens hologram .

As described above, in the hologram three-dimensional glasses of the present invention, a hologram projector is inserted into an eyeglass frame, a hologram projector irradiates a hologram on the entire surface of the lens, and a lens hologram having a dioptric function is formed. The lens of the eye is thicker and heavier than the lens of the other eye and can be prevented from tilting to one side, and it is possible to improve the aesthetics and convenience of the spectacles as well as form a lens to help the wearer correct their eyesight.

1 is an exploded perspective view showing a configuration of hologram three-dimensional glasses having a can type cover according to the related art,
FIG. 2 is a perspective view showing a configuration of hologram three-dimensional glasses worn on one eye according to an embodiment of the present invention;
FIG. 3A is a perspective view showing a configuration of hologram three-dimensional glasses worn on both eyes according to another embodiment of the present invention,
FIG. 3B is a perspective view showing a configuration of hologram three-dimensional glasses in which a projector is mounted on a nose pad according to another embodiment of the present invention;
4 is a block diagram showing the configuration of an interference light hologram projector according to the present invention.
5 is a cross-sectional view showing a state in which a lens hologram having a dioptric function is formed on hologram three-dimensional glasses worn on both eyes according to the present invention,
6 is a block diagram showing the configuration of a reference light hologram projector according to the present invention.
7A and 7B are block diagrams respectively showing the configurations of the interference light projector and the reference light projector of the hologram three-dimensional glasses having the augmented reality function according to the present invention,
FIG. 8 is a diagram showing a state in which geographic information data is provided in an urban area through hologram 3D glasses having an augmented reality function according to the present invention.

The embodiments of the present invention can be modified into various forms and the scope of the present invention should not be interpreted as being limited by the embodiments described below. The present embodiments are provided to enable those skilled in the art to more fully understand the present invention. Therefore, the shapes and the like of the components in the drawings are exaggerated in order to emphasize a clearer explanation.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 2 is a perspective view showing the configuration of the hologram 3D glasses worn on one eye according to an embodiment of the present invention. FIG. 3A shows a hologram 3D glasses worn on both eyes according to another embodiment of the present invention. 3B is a perspective view showing a configuration of a hologram three-dimensional glasses in which a projector is provided on a nose pad according to another embodiment of the present invention.

Referring to FIG. 2, the hologram 3D glasses 100 of the present invention includes a support 10 supporting a lens or a protective glass 20 positioned on the front of the eye 210; A lens or a protective lens 20 attached to the support 10 and installed on the front surface of the eye 210; An interference light projector 30 installed on the nose 10 of the support 10 to form an interference optical hologram 111 on the entire surface of the lens or the protective glass 20; And a reference light projector 40 provided on a front surface of the ear hook support portion 12 of the support frame 10 to form a reference light hologram 112 on the front surface of the lens or the protective lens 20. [

The support base 10 according to the present invention may be an eyeglass frame or the like. In this embodiment, the nose 231 of the wearer 200 is worn on the eyes 210 of the wearer 200, And an ear hook support portion 12 that extends between the nose pin 11 and the upper ear wheel 221 of the ear 220 of the wearer 200 and the head 240.

The support base 10 according to the present invention is made of an elastic material and is hooked on the right inclined face of the nose root 231 of the wearer 200 and the nose root hook 11 is fastened to the ear 220 And can be worn on the wearer's nose roots 231 and ears 220 without falling by gravity.

In this embodiment, one lens or protective glass 20 is provided on the support 10 because it is worn on one eye 210 of the wearer 200. However, as shown in FIG. 3A, Two lenses or protective lenses 20 are provided so as to be worn on the left and right ears 210 and two ear pieces 12 are provided on the left ear and the right ear so that the interference light projector 30 and the reference light projector 30, The hologram 110 may be formed on the entire surface of the two lenses or the protective lens 20 worn on both eyes 210 by adding the lens 40. [

The lens or the protective glass 20 according to the present invention is installed on the support 10 so as to cover the entire surface of the eye 210 of the wearer 200 to refract or filter the light incident from the front of the wearer 200 The eye 210 of the wearer 200 is corrected or the harmful light such as ultraviolet rays is blocked to protect the eyes 210.

The hologram projector 30 according to the present invention is installed on the front part of the nose hooking part 11 and the ear hook supporting part 12 of the support frame 10 and the hologram 110, so that a lens hologram, a vision correction hologram, and the like can be formed to perform a vision correction or a vision correction exercise of the wearer 200.

The interference light projector 30 provided on the nose root hooking portion 11 that spans the nose root 231 of the wearer 200 irradiates the entire surface of the lens or the protective glass 20 with the interference light hologram 111 And the reference light projector 40 provided on the front surface of the ear hook support part 12 irradiates the reference light hologram 112 so that the interference light hologram 111 and the reference light hologram 112 are combined to form a lens hologram, A hologram 110 such as a calibration hologram is formed.

As shown in FIG. 3B, the left and right nose pads 15, which are made of silicone resin and adhered to the nose 230 of the wearer 200, are coated with an interference light projector 30 And a reference light projector 40 are installed to project a hologram 110 in front of the left and right eyes 210 of the wearer 200 to form an intricate lens hologram and a vision correction hologram, Vision correction exercise and so on.

The left or right nose pad 15 is provided with a lens or a protective glass 20 so as to be attached to the nose 230 of the wearer 200 so that the lens or protective glass 20 is positioned in front of the left and right eyes 210 .

FIG. 4 is a block diagram showing the construction of an interference optical hologram projector according to the present invention. FIG. 5 shows a state in which a lens hologram having a dioptric function is formed on hologram three-dimensional glasses worn on both eyes according to the present invention A cross-sectional view is shown.

The interference light hologram projector 30 according to the present invention may be a computer generated hologram (CGH) data of an incumbent lens obtained by a mathematical operation of an interference light hologram data, for example, a computer generated hologram (CGH) (CRH) data of a vision correcting lens obtained through an operation of the laser light source, and irradiates the interference light hologram with a laser to form an interference optical lens hologram on the entire surface of the lens or the protective lens 20 31); A graphic processing unit 32 for receiving the interference light hologram data from the interference light hologram storage unit 33 and processing the interference light hologram data to be a three dimensional hologram under the control of the interference light projector control unit 34 and outputting the processed data to the laser generation unit 31 ; Computer-generated hologram (CGH) data obtained through mathematical calculations on interfering optical hologram data, such as a diopter lens, a vision correction lens, and the like, and controls the interference optical hologram An interference light hologram storage unit (33) for outputting data to the graphic processing unit (32); Controls the interference light hologram storage unit 33 to output interference light hologram data such as hologram data of holograms and hologram data of the vision correction lens to the graphic processing unit 32, Dimensional interference light hologram is input to the laser generation unit 31 to form an interference optical lens hologram, the controller 30 controls the laser light generator 31 to process the interference light hologram data to output a three-dimensional interference light hologram, (34); The projector control unit 34 detects an electrical signal generated in the optic nerve of the wearer 200 and inputs the signal to the projector control unit 34 so that the lens hologram 110 corresponding to the visual acuity of the wearer 200 is received by the lens or the protective glass And an optic nerve sensor 35 for forming the optic nerve sensor 35 on the front surface of the optic nerve head 20.

The laser generation unit 31 according to the present invention includes a laser light emitting diode and is controlled by the projector control unit 34 to output the interference hologram data, for example, lens hologram data having an irregular lens shape to the graphic processing unit 32 The interference light hologram 111 is formed on the entire surface of the lens or the protective lens 20 as shown in FIG.

The graphic processing unit 32 of the present invention performs a mathematical operation on the interference light hologram data, for example, a computer-generated hologram (CGH) of the hologram object in the interference light hologram storage unit 33 (Hologram) computer generated hologram (CGH) data obtained through the control of the projector control unit 34 under the control of the projector control unit 34 to process the three-dimensional hologram 110. For example, a plurality of streaming multiprocessors (Hologram CGH), which is mathematically defined, and outputs the processing result to the laser generation unit 31.

The interference light hologram storage unit 33 according to the present invention stores computer generated hologram (CGH) data of a portable lens obtained through a mathematical operation, for example, an equation representing a computer generated hologram (CGH) Computer generated hologram (CGH) data obtained by mathematical calculation of a mathematical expression representing a computer generated hologram (CGH) of a correcting lens and the like are stored in the computer generated hologram And outputs the interference light hologram data of the CGH data to the graphic processing unit 32.

Here, the mathematical expression representing the computer generated hologram (CGH) of the lens having various dioptric power is processed through a mathematical operation to store the computer generated hologram (CGH) data of the lens having various dioptric powers, and if necessary, To generate computer generated hologram (CGH) data of a lens having a lens.

The projector control unit 34 according to the present invention may calculate interference light hologram data stored in the interference light hologram storage unit 33, for example, a mathematical expression representing a computer generated hologram (CGH) (CGH) data of a vision-correcting lens to the graphic processing unit 32, and the graphic control unit 32 controls the graphic control unit 32 to output the coherent light hologram data Dimensional interference fringe hologram to output the three-dimensional interference fringe hologram, and the three-dimensional interference fringing hologram is input to the laser generation unit 31 to form an interference light lens hologram.

The optic nerve sensor 35 according to the present invention senses an electrical signal generated by the optic nerve of the wearer 200 in response to light and inputs the sensed signal to the projector control unit 34 so that the projector control unit 34 controls the wearer 200, The lens hologram 110 is formed on the entire surface of the lens or the protective glass 20.

6 is a block diagram showing a configuration of a reference light hologram projector according to the present invention.

6, the reference light hologram projector 40 replaces the interference light hologram storage unit 33 of the interference light hologram projector 30 shown in Fig. 4 with the reference light hologram storage unit 43, and the projector control unit 44) processes the reference light hologram data by the graphic controller 42 to output a three-dimensional reference light hologram, and the three-dimensional reference light hologram is input to the laser generator 41 to convert the reference light lens hologram into a lens or a protective lens (Not shown), so that the description will be omitted.

7A and 7B are block diagrams respectively showing the configurations of the interference light projector and the reference light projector of the hologram three-dimensional glasses having the augmented reality function according to the present invention. Fig. 8 shows a hologram And the geographic information data is provided to the urban area through the 3D glasses.

GPS receivers 36 and 46 and wireless communication units 37 and 47 are added to the interference light projector 30 and the reference light projector 40 in order to have the augmented reality function in the hologram three-dimensional glasses 100 according to the present invention .

The GPS receivers 36 and 46 receive the GPS data from the GPS satellites and calculate the positional information of the wearer 200 wearing the hologram 3D glasses 100 according to the present invention and input them to the projector controllers 34 and 44 do.

The projector control units 34 and 44 receive position information from the GPS receivers 36 and 46 and transmit the position information to the geographical information server through the wireless communication unit 37 to receive the geographical information data.

The geographical information data received from the geographical information server is superimposed on the lens hologram 110 as shown in FIG. 8, and the geographical information data is displayed on the lens hologram 110 through the wearer 200, for example, , An address, a name of a street, and the like, to provide an augmented reality service.

The embodiments of the present invention described above are not implemented only by the apparatus and / or method, but may be implemented through a program for realizing functions corresponding to the configuration of the embodiment of the present invention, a recording medium on which the program is recorded And such an embodiment can be easily implemented by those skilled in the art from the description of the embodiments described above.

10: Support 11:
12: ear hook support 15: nose pad
20: Lens or protective gear
30: interference optical projector 31, 41: laser generator
32, 42: Graphic processing section 33: Interfering light hologram storage section
34, 44: projector control section 35, 45:
36, 46: GPS receiver 37, 47:
40: reference light projector 43: reference light hologram storage unit
100: Hologram 3D glasses 110: Hologram
111: interference optical holography 112: reference light hologram

Claims (9)

A support for supporting a lens or a protective lens positioned on the front of the eye;
A lens or protective liner attached to the support and installed on the front of the eye;
An interference light projector provided on the support and forming an interference optical hologram on the entire surface of the lens or the protective mirror;
And a reference light projector mounted on the opposite side of the interference light projector with respect to the lens or the protective lens to form a reference light hologram on the front surface of the lens or the protective mirror. The method according to claim 1,
Wherein the support base includes a nose root support portion which is worn on the wearer's eye and is supported on the nose of the wearer so as to support the lens or the protective sheath, Three-dimensional glasses. The method according to claim 1,
Wherein the support is a left and right nose pad made of a silicone resin and adhered to a nose of a wearer. 3. The method according to claim 1 or 2,
The support base is made to be worn on both eyes of the wearer and two lenses or a protective glass are provided on a support base made to be worn on both eyes and the earbud support is made to cover the left ear and the right ear. Wherein a hologram is formed on a front surface of a lens or a protective lens which is worn on both eyes. 3. The method according to claim 1 or 2,
The interference light projector irradiates the interference light hologram and the reference light projector is configured to irradiate the reference light hologram to form a hologram of a lens hologram and a vision correction hologram in which the interference light hologram and the reference light hologram are combined, Hologram 3D glasses with. 3. The method according to claim 1 or 2,
The interference light hologram projector includes:
(CRH) data of the lens obtained by a mathematical operation to obtain a computer-generated hologram (CGH) of the lens, so that an interference light A laser generating unit for forming a lens hologram;
A graphic processing unit for receiving the interference optical computer generated hologram (CGH) data of the lens in the interference light hologram storage unit to process the hologram data into a three-dimensional hologram and output it to the laser generation unit;
The computer-generated hologram (CGH) data of the lens obtained by a mathematical operation is stored in an equation representing a computer generated hologram (CGH) of the lens, and the interference optical computer generated hologram (CGH) An interference light hologram storage unit for outputting the interference light hologram to the processing unit;
Controls the interference light hologram storage unit to output the interference light hologram data to the graphic processor, and controls the graphic controller to process the interference light hologram data to output the interference light hologram data, A projector control unit for controlling the laser generating unit to form an interference optical lens hologram;
And an optic nerve sensor for sensing an electrical signal generated by the optic nerve of the wearer and inputting the electrical signal to the projector control unit so that the projector control unit forms a lens hologram corresponding to the wearer's vision on the front surface of the lens or the protective nerve,
Wherein the reference light hologram projector has a reference light hologram storage unit instead of the interference light hologram storage unit. The method according to claim 6,
The graphic processing unit receives interference light or reference light computer generated hologram data obtained through a mathematical operation of a mathematical expression representing a computer generated hologram of the lens in the interference light hologram storage unit or the reference light hologram storage unit, Processing the hologram to be a hologram, and processing mathematically defined computer-generated holograms (CGH) in parallel and outputting the processed holograms to the laser generator. The method according to claim 6,
The interference light hologram storage unit and the reference light hologram storage unit store computer generated hologram (CGH) data of lenses having various dioptric powers and output computer generated hologram (CGH) data of a lens having a power corresponding to the visual acuity of the wearer Wherein said holographic three-dimensional glasses are made of glass. The method according to claim 6,
Wherein a GPS receiver and a wireless communication unit are added to the interference light projector and the reference light projector so that the geographical information data is superimposed on the lens hologram and the wearer is provided with an augmented reality service through the lens hologram.

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