KR20130047843A - Three dimensions laser animation display system - Google Patents

Abstract

PURPOSE: A three dimensional laser video displaying system is provided to show an excellent color reproduction range by installing and using a polarizing filter in which is perpendicularly polarized in a rear end of two laser projectors of binocular parallax application which has a narrower unit wavelength range than the general light source. CONSTITUTION: A three dimensional camera(100) takes a picture by applying a binocular parallax to an object in which will be made into a video. A management server(200) comprises a receiving unit(210), a converting unit(220), a synchronization unit(230), an optical axis adjustment unit(240), a transmission unit(250), and a database unit(260). A laser projector(300) is made of a pair receives left-eye video data and right eye video data transmitted from the management server. A polarizing filter(400) receives an image signal from a pair of laser projector, and the polarization direction are perpendicular. A projection screen(500) displays the image signal passed the polarizing filter into a screen as a video. [Reference numerals] (100) 3D camera; (200) Server; (210) Receiving unit; (220) Converting unit; (230) Synchronization unit; (240) Optical axis adjustment unit; (250) Transmission unit; (260) Database unit; (300) Laser projector; (400) Polarizing filter; (500) Projection screen; (600) 3D glasses; (700) Polarizing filter fixing device; (800) Mounting device; (AA) 3D image data; (BB) Image data for left eye; (CC) Image data for right eye

Description

Three-dimensional laser animation display system

The present invention has excellent performance of color reproducibility by installing polarizing filters that are polarized perpendicular to each other at the rear end of two laser projectors having a very narrow unit wavelength range compared to a general light source. By installing the polarization filter fixing device, the optical axis can be aligned so that the polarization directions are exactly perpendicular to the light exiting portions of the pair of laser projection modules, and the left eye image and the right eye image viewed through the 3D glasses are projected through the projection screen. By using a laser projector that is different from the image of a normal light source, the image can be seen at 200% color and the difference between the left and right images for the two projectors. Mounted on a mounting device that can be fixed by moving and rotating alignment in the Z axis, respectively. In addition, the user can feel 3D through the image difference between left and right eyes, and by using the optical axis adjustment unit inside the server, the optical axis adjustment software for the 3D projector can be accurately corrected for the pair of mutually polarized laser projectors. By adjusting the built-in MEMS laser projection module in the laser projector, the compact size of the fast-driving MEMS driver can make the system compact and cost-effective, and can reproduce up to 90% of natural colors. By using, you can accurately and beautifully express characters, companies, mascots, and characters that are unique characteristics of the product, and apply them to company logos and videos in the fields of self-promotion, architectural presentations, scientific presentations, sports and cultural arts performances. 3D laser video display A description of the system.

Recently, with the development of 3D imaging technology, an exploding three-dimensional display market is being formed, and mass production of low-cost small laser displays is in progress. One of the desires that appear naturally within humans with the development of technology is that they want to be able to access more lively and realistic contents for mass media and promotional materials on one screen. A TV-class three-dimensional video laser display that can reproduce near natural colors can fully reflect these characteristics.

As an example of the character market described above, the US character market is a market that has been formed for several hundred years, including 50 trillion won in 2009, 13 trillion won in Japan, and 4 trillion won in Korea.

In addition, the three-dimensional laser display has the advantage of delivering realistic three-dimensional characters (characters, logos and merchandise characteristics, content with other unique characteristics) to the customer vividly with natural colors. Therefore, it will be easy to enter such a huge blue ocean market.

Until 2005, 3D stereo technology was in the pre-utilization stage, mainly focusing on R & D and testing of technology and principles. Since 2008, it is possible to approach the commercialization stage and mass-produce through realistic methods, and began to commercialize in various fields of the world, and the fields of application such as broadcasting, games, advertising, design, and education are expanding.

According to the Korea Electronics and Telecommunications Industry Promotion Association (KEA), the market for 3D-related industries is expected to grow rapidly from 4 trillion 900 trillion won in 2009 to 62 trillion won by 2015. It's a big bang that's equivalent to the shift from analog to digital.

Therefore, three-dimensional laser display contents that are close to natural colors for characters and three-dimensional markets will bring explosive demand in the economic industry.

Therefore, the development of a three-dimensional laser video display system is urgently required for users who have excellent color reproducibility close to natural colors and try to make three-dimensional images.

The present invention has been conceived to solve the above problems, by using a polarization filter that is polarized perpendicular to each other at the rear end of the two laser projectors of the unitary wavelength range is very narrow compared to the general light source application of binocular parallax, color reproduction rate The purpose is to provide a three-dimensional laser video display system having this excellent performance.

Another object of the present invention is to provide a three-dimensional laser video display system capable of aligning the optical axis so that the polarization direction is exactly perpendicular to each other in the light exit portion of the pair of laser projection module by installing a polarization filter fixing device at the rear end of the laser projector To provide.

Another object of the present invention is to use a laser projector different from the image of the general light source when the image for the left eye and the right eye viewed through the 3D glasses through the projection screen, showing a color reproduction rate of 200% To provide a three-dimensional laser video display system that can feel the difference between the left and right images for the two projectors.

Another object of the present invention is that the two laser projectors are mounted on the mounting device that can be fixed by moving and rotationally aligned in the X, Y, Z axis, respectively, 3 to feel the three-dimensional through the image difference between the left and right eyes To provide a three-dimensional laser video display system.

Another object of the present invention is to provide a three-dimensional laser video display system that can accurately adjust the optical axis by using the optical axis adjustment software for the 3D projector for a pair of mutually polarized laser projector by embedding the optical axis adjustment unit inside the server It is.

Another object of the present invention is to provide a three-dimensional laser video display system that can bring a compact and cost-effective system due to the miniaturization characteristics of the MEMS drive body with a fast drive speed by embedding the MEMS laser projection module in the laser projector It is.

Another object of the present invention is to provide a three-dimensional laser video display system capable of accurately and beautifully expressing characters, companies, mascots, and characters that are unique characteristics of a product by using a laser projector that can reproduce up to 90% of natural colors.

Another object of the present invention is to provide a three-dimensional laser video display system that can be applied to the image of the company logo and self-product promotion, architectural presentation, scientific presentation, sports and cultural arts performance.

3D laser video display system according to an embodiment of the present invention for achieving the above object is a 3D camera for photographing the object to be produced as a video by applying binocular parallax; A receiver for receiving 3D image data captured by the 3D camera, a converter for converting the received 3D image data into data suitable for transmission to a laser projector, a left eye image data and a right eye image A synchronization unit for synchronizing data, an optical axis adjusting unit for precisely adjusting the optical axis of the laser projector using optical axis adjusting software, and a transmitting unit for transmitting the synchronized and optical axis-adjusted left eye image data and right eye image data to a laser projector A management server including a database unit for storing the transmitted image data; A pair of laser projectors receiving left eye image data and right eye image data transmitted from the management server; A polarization filter in which polarization directions of receiving image signals from the pair of laser projectors are perpendicular to each other; A projection screen for displaying an image signal passing through the polarization filter as an image on a screen; 3D polarized glasses for viewing the image displayed on the projection screen as a three-dimensional image; .

In the present invention, the 3D camera uses a mount ring type 3D camera using two cameras on the mount, an integrated 3D camera capable of correcting and optimizing stereoscopic images, and two general camcorders. It characterized in that it comprises any one of the 3D camera.

In the present invention, the polarization filter is fixed to the rear end of the laser projector, the polarization filter is fixed so that the image signal from the laser projector is accurately displayed on the screen of the screen through the polarization filters perpendicular to each other polarization direction It further comprises a device.

In the present invention, the pair of laser projector is characterized in that it further comprises a mounting device for fixing the laser projector using a solenoid actuator to be moved and rotated aligned in the X, Y, Z axis respectively.

In the present invention, the projection screen is characterized in that it comprises a normal screen or silver screen.

In the present invention, the polarization filter is a linear polarization filter or a circular polarization filter, when using the linear polarization filter or circular polarization filter, the two projectors are polarized at right angles to each other, the left eye of the left eye projector and glasses The polarization direction of the lens is the same, and the polarization direction of the right eye lens of the right eye projector and the spectacles includes the same.

In the present invention, the use of the linear polarization filter or the circular polarization filter is time multipelxing, light polarization, dual projection image, beam splitter, anaglyph ( Anaglyph) is characterized in that it can be selected and replaced.

In the present invention, the three-dimensional laser video display system is characterized in that it can be applied to the image of the company logo and self-product promotion, architectural presentation, scientific presentation, sports and cultural arts performance.

The 3D laser video display system according to the present invention has the following effects.

First, the present invention has excellent performance of color reproducibility by using polarizing filters that are polarized perpendicularly to each other at the rear end of two laser projectors having a very narrow unit wavelength range compared to a general light source.

Second, the present invention can be arranged in the rear end of the laser projector, the optical axis can be aligned so that the polarization direction is exactly perpendicular to the light exit portion of the pair of laser projection module.

Third, the present invention shows a 200% color reproduction rate by using a laser projector different from the image of a general light source when the image for the left eye and the right eye viewed through the 3D glasses are viewed through the projection screen. You can feel the difference between left and right images for two projectors.

Fourth, the present invention is mounted on a mounting apparatus that can be fixed by moving and rotationally aligned to the X, Y, Z axis, respectively, so that the three-dimensional feel through the image difference between the left and right eyes.

Fifth, the present invention incorporates an optical axis adjustment unit inside a server, so that the optical axis can be accurately adjusted using optical axis adjustment software for a 3D projector with respect to a pair of mutually polarized laser projectors.

Sixth, the present invention can provide a compact system as well as a cost reduction by incorporating the MEMS laser projection module in the laser projector, due to the miniaturization characteristics of the MEMS driver having a fast driving speed.

Seventh, the present invention can accurately and beautifully express a character, a company, a mascot, and a character that is a unique characteristic of a product by using a laser projector that can reproduce up to 90% of natural colors.

Eighth, the present invention can be applied to company logos and images of self-product promotion, architectural presentation, scientific presentation, sports and cultural art performance.

1 is a view showing the configuration of a three-dimensional laser video display system according to an embodiment of the present invention.
2A to 2C are photographic views illustrating 3D cameras used in a 3D laser video display system according to an embodiment of the present invention.
Figure 3 is a view showing a color comparison table for each medium applied to the three-dimensional laser video display system according to an embodiment of the present invention.

Looking at the preferred embodiment of the present invention together with the accompanying drawings as follows, when it is determined that the detailed description of the known art or configuration related to the present invention may unnecessarily obscure the subject matter of the present invention The description will be omitted, and the following terms are terms defined in consideration of functions in the present invention, which may vary according to a user's intention or an operator's intention or custom, and the definitions of the present invention describe the 3D laser video display system. It should be made based on the contents throughout the specification.

Hereinafter, a 3D laser video display system according to an exemplary embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a view showing the configuration of a three-dimensional laser video display system according to an embodiment of the present invention, Figures 2a to 2c is a 3D camera used in the three-dimensional laser video display system according to an embodiment of the present invention It is a photographic figure showing.

As shown in FIGS. 1 to 2C, the 3D laser video display system includes a 3D camera 100, a management server 200, a receiver 210, a converter 220, a synchronizer 230, and an optical axis adjuster ( 240, transmitter 250, database unit 260, laser projector 300, polarization filter 400, projection screen 500, 3D glasses 600, polarization filter fixing device 700, mounting device 800 ), And the like.

The 3D laser video display system of the present invention includes a 3D camera 100 for photographing a subject to be produced as a video by applying binocular parallax; A receiver 210 for receiving 3D image data captured by the 3D camera, a converter 220 for converting the received 3D image data into data suitable for transmission to a laser projector, and the converted data for a left eye A synchronization unit 230 for synchronizing the image data with the right eye image data, an optical axis adjusting unit 240 for precisely adjusting the optical axis of the laser projector using optical axis adjustment software, and the synchronized and optical axis adjusted left eye image data A management server 200 including a transmitter 250 for transmitting right eye image data to a laser projector, and a database unit 260 for storing the transmitted image data; A pair of laser projectors 300 for receiving left eye image data and right eye image data transmitted from the management server; A polarization filter 400 in which polarization directions of receiving image signals from the pair of laser projectors are perpendicular to each other; A projection screen (500) for displaying an image signal passing through the polarization filter as an image on a screen; 3D polarized glasses 600 to view an image displayed on the projection screen as a three-dimensional image; Respectively.

Looking at the function of the technical means constituting the three-dimensional laser video display system of the present invention as follows.

The 3D camera 100 is to shoot a target to produce a video by applying binocular parallax. As shown in FIG. 2, the 3D camera 100 includes a mount ring type 3D camera using two cameras mounted on a mount, an integrated 3D camera capable of correcting and optimizing stereoscopic images, and Either 3D cameras using two standard camcorders.

The management server 200 is a receiving unit 210 for receiving the 3D image data taken by the 3D camera, a conversion unit 220 for converting the received 3D image data into data suitable for transmission to a laser projector, A synchronization unit 230 for synchronizing the converted data with the left eye image data and the right eye image data, and an optical axis adjusting unit 240 for precisely adjusting the optical axis of the laser projector using optical axis adjustment software, And a transmitter 250 for transmitting the optical axis adjusted left eye image data and the right eye image data to a laser projector, and a database unit 260 for storing the transmitted image data.

There are two or one laser projectors 300, and the left eye image data and the right eye image data transmitted from the management server are received. Here, the pair of laser projector is to fix the laser projector by using a mounting device 800 of the solenoid actuator type to be moved and rotated aligned in the X, Y, Z axis, respectively. The color reproducibility is 65% for LCD, 95% for PDP, and only 120% for AMOLED, but the laser applied to the present invention is 200%, which is higher than other devices.

The polarization filter 400 is a polarization direction receiving the image signal from the pair of laser projector is perpendicular to each other. Here, the polarization filter 400 is installed and fixed to the rear end of the laser projector, the polarization filter to display the image signal from the laser projector is accurately displayed on the screen of the screen through the polarization filter perpendicular to each other polarization direction It is fixed by the fixing device 700.

In addition, the polarization filter 400 is a linear polarization filter or a circular polarization filter, when using the linear polarization filter or circular polarization filter, the two projectors are polarized at right angles to each other, the left eye projector and the left eye lens of the glasses The polarization directions are the same, and the polarization directions of the right eye projector and the right eye lens of the glasses are the same, and the use of the linear polarization filter or the circular polarization filter is used for time multipelxing, light polarization, and dual projection images. Dual projection, beam splitter and anaglyph can be selected and replaced.

Here, the anaglyph method is a method of implementing a 3D image using a color difference, and the image of the left eye is formed in blue, the image of the right eye is formed in red, and is then overlapped and projected on the screen. The left eye is blue and the right eye has a filter with red filter. In addition, the beam splitter is an optical device for generating two or more beams in one beam. The light polarization is a phenomenon in which the direction distribution of the vibration vector of the light is not uniform, and the vibration is limited in a specific plane in the vibration of the transverse wave, and normal light vibrates in all directions in the plane perpendicular to the traveling direction. Although it is made of light waves, it refers to light that vibrates only in a certain direction.

The projection screen 500 is to allow the image signal passing through the polarization filter to be displayed as an image on the screen. In this case, the projection screen 500 may be a normal screen or a silver screen, but a screen made of cloth with less reflection may be used.

The 3D polarized glasses 600 are to enable to view the image displayed on the projection screen as a three-dimensional image.

3 is a diagram illustrating a color comparison table for each medium applied to a 3D laser video display system according to an exemplary embodiment of the present invention.

As shown in FIG. 3, in the case of laser, UHP lamp projection, LCD TV, and NTSC, looking at the color range according to chromaticity, it can be seen that the range of the laser is the widest. . This indicates that the laser expresses colors better than other media.

As described above, the three-dimensional laser video display system of the present invention has excellent color reproducibility and can align the optical axes such that the polarization directions are exactly perpendicular to each other at the light exit portions of the pair of laser projection modules, and 200% In addition to showing the color reproducibility of the two projectors, you can feel the difference between the left and right image, and the three-dimensional image through the left and right eye image difference.

It will be appreciated by those skilled in the art that the present invention is not limited to the above embodiments, and that various modifications and changes can be made without departing from the spirit of the present invention.

As described above, the three-dimensional laser video display system of the present invention displays a self-contained product image along with a logo of a unique company and content that is animated in three dimensions and vividly in three dimensions with a laser-specific color and TV expression that a general light source cannot express. With the unique and subtle color difference of the laser, the interior of the building is made with the unique and subtle color difference of the laser, along with the company logo that expresses uniquely and the self-promotion of the product, and the natural beauty of the natural color reproduced by the 3D camera. Movements in the field of architectural presentations that can deliver the value of buildings to audiences by visualizing them from the outside, and movements in particle accelerators such as the universe of unique colors, aerial images of natural landscapes, complex DNA structures, and electrons. Motion of water, water, or smoke particles cannot be shown on a regular TV. The science of parts that could not be shown to the audience by creating and expressing contents with 3D animation videos that can distinguish the inside and the outside of objects or materials with the unique and minute color difference of the laser with a lively and realistic feeling State-of-the-art augmented reality content, in which presentations and computer-generated characters overlap with the real world, displays characters such as soccer or figure skaters, actors and performers in cultural arts, and images of unique light. Combined with the real picture on the screen, it can be applied to the sports and cultural art performance field that can show the audience as if they are running in fantasy and reality with realistic images of the laser.

100: 3D camera 200: management server
210: receiver 220: converter
230: synchronization unit 240: optical axis adjustment unit
250: transmitter 260: database
300: laser projector 400: polarization filter
500: Projection Screen 600: 3D Glasses
700: polarization filter fixing device 800: mounting device

Claims (8)

In the three-dimensional laser video display system,
A 3D camera for shooting a target to be produced as a video by applying binocular parallax;
A receiver for receiving 3D image data captured by the 3D camera, a converter for converting the received 3D image data into data suitable for transmission to a laser projector, a left eye image data and a right eye image A synchronization unit for synchronizing data, an optical axis adjusting unit for precisely adjusting the optical axis of the laser projector using optical axis adjusting software, and a transmitting unit for transmitting the synchronized and optical axis-adjusted left eye image data and right eye image data to a laser projector A management server including a database unit for storing the transmitted image data;
A pair of laser projectors receiving left eye image data and right eye image data transmitted from the management server;
A polarization filter in which polarization directions of receiving image signals from the pair of laser projectors are perpendicular to each other;
A projection screen for displaying an image signal passing through the polarization filter as an image on a screen;
3D polarized glasses for viewing the image displayed on the projection screen as a three-dimensional image; Three-dimensional laser video display system comprising a. The method of claim 1,
The 3D camera is any one of a mount ring type 3D camera using two cameras on a mount, an integrated 3D camera capable of correcting and optimizing stereoscopic images, and a 3D camera using two general camcorders. 3D laser video display system comprising a. The method of claim 1,
Fixing the polarization filter installed at the rear end of the laser projector, and further comprising a polarization filter fixing device for the image signal from the laser projector to be accurately displayed on the screen of the screen through the polarization filter perpendicular to each other polarization direction; 3D laser video display system. The method of claim 1,
And a mounting device for fixing the laser projector using a solenoid actuator so that the pair of laser projectors are moved and rotated in the X, Y, and Z axes, respectively. The method of claim 1,
And the projection screen includes a normal screen or a silver screen. The method of claim 1,
The polarization filter is a linear polarization filter or a circular polarization filter, and when the linear polarization filter or circular polarization filter is used, two projectors are polarized at right angles to each other, and the polarization directions of the left eye projector and the left eye lens of the glasses are the same. And a polarization direction of the right eye projector and the right eye lens of the glasses includes the same. The method according to claim 6,
The linear polarization filter or the circular polarization filter is used to select from among time multipelxing, light polarization, dual projection, beam splitter, and anaglyph method. 3D laser video display system, characterized in that it comprises a replaceable. The method of claim 1,
3D laser video display system, which can be applied to company logos and images of self-product promotion, architectural presentations, scientific presentations, sports and cultural arts performances.

Images