ES2264846B1 - PROCEDURE FOR THE MANUFACTURE OF STEREOSCOPICAL VISUALIZATION MONITORS. - Google Patents

Abstract

Procedure for the manufacture of stereoscopic display monitors that consists in allowing the adaptation of the same to the final polarization carried out by the TFT-LCD monitors or any other type, being composed of two monitors (1) and (2) or (20) and (21) with an angular offset of 90 ° with respect to the final polarization, glasses or frames being used for three-dimensional visualization.

Description

Procedure for manufacturing monitors Stereoscopic display.

Object of the invention

The present specification refers to a application for an Invention Patent corresponding to a procedure for manufacturing display monitors stereoscopic, whose purpose is to adapt the system to the final polarization of the monitors TFT-LCD, or any other type, giving as result a three-dimensional monitor composed of two monitors with  an angular offset of 90º with respect to the final polarization that effect each of them, and thus the polarization of the glasses would also have a 90º offset in their polarization.

Field of the Invention

This invention has its application within the industry dedicated to the manufacture of apparatus for stereoscopic display.

Background of the invention

The applicant has knowledge of some systems intended to obtain images three-dimensional, most of which have drawbacks that advise against its use.

On the contrary, the applicant is the holder of the Invention Patent requested in Spain with the number 9001428 and published with the number 2,024,269 relative to an optical system for three-dimensional vision, which describes and claims a optical system that gives rise to a three-dimensional vision, being based on the use of two images reproduced by two twin televisions, positioned so that their angle screens straight, having a 45º equidistant crystal between the two screens, on which polarizers that act in a 90º angle to each other.

The invention is complemented using glasses polarizers, the angle of polarization of each eye being the same as the screen whose image they receive respectively, both polarizing filters can perform a 90º turn.

However, the applicant does not is aware of the current existence of a invention that presents the characteristics described in this memory.

Description of the invention

The procedure for manufacturing stereoscopic display monitors that the invention proposes, incorporates notable advantages over known techniques applicable on television monitors and receivers, computers and video games, as well as photographs translucent, semi-transparent, films dura-trans and, in general, for any image formed by points or luminous masses.

More specifically, the procedure for Stereoscopic display monitor manufacturing is constituted from the adaptation of the invention to the final polarization of the monitors TFT-LCD or any other type, since in this type of monitors the image displayed is polarized and, According to the manufacturer, model or screen size, the angle of this polarization may vary for the monitor application three-dimensional, the invention being composed by two monitors with an angular offset of 90º with respect to the final polarization that each of them carries out, and in this way the polarization of the glasses required for the display of the images would also have a 90º offset in its Polarization.

If the pair of TFT-LCD monitors or of any other type, or some other image generator based on polarization once incorporated into the system produces a lag angular in their polarizations other than 90º, the polarizers built into glasses or special frames that replace these, they will not have an angular offset of 90º in their polarization, and the angle of polarization of each of the eyes will be determined simply by a 90º angular offset with regarding the polarization of the monitor that should be inhibited visually to each eye.

In this way stereoscopic information is correctly distributes to their respective eye and the formation of the three-dimensional image in the brain is correct, although there is a loss of brightness with respect to the resulting image described previously, and also the polarization position in the glasses It is more critical and requires much more precision, but in this way the possibility of using any monitor model is extended existing in the market.

In the invention filters are used polarizers applicable to stereoscopic cameras that are recording or broadcasting images of a stage or space in which one or more three-dimensional monitors are present, performing the application of polarizers to the chambers of similar to the application made to the glasses of a observer, since the left chamber would be placed a polarizer coinciding with the same polarization angle of the monitor that reproduces the image for the left eye or 90º out of phase with respect to the monitor that reproduces the image aimed at the right eye, and a right camera would be attached polarizer matching the polarization angle of the monitor responsible for reproducing the image for the right or outdated eye 90º with respect to the monitor that generates the image for the eye left.

With this application you get the stereoscopic images captured by cameras can reproduce the three dimensions, not only of the real filmed space but also of the images that are observed in the monitors that are part of the surroundings or decorated.

The invention contemplates the possibility of use outer polarized racks to facilitate visualization of the three-dimensional images generated by the monitors without the use of glasses, being able to be composed of the frames by passive polarizers applied from analogous shape in relation to the position and angle of polarization than to the glasses, and to these two polarization fields, one for each eye, you can apply various designs of form and sizes.

The polarization fields can also be composed of liquid crystals in order to achieve different effects on visual information, since these crystals give us allow to change the polarization angle by electrically exciting one or both fields according to the intended effect.

The glasses will be provided with crystals or Plastics with offset angles 90º in shape analogous to that described above and, in order to get that the observer has total freedom of movement without losing the three-dimensional vision, they will be provided with a free system angular balancing, consisting of a small overweight in the part bottom of each filter or filter holder that, taking advantage of the gravity force, rotate the filters and keep polarization angles of the glasses always with the same position angular with respect to the two polarization fields generated in the monitor.

In the invention the filters are replaced polarizers used in glasses by crystal polarizers liquid that achieve the same purpose described above and, in In this case, each glass of the glasses will be managed by fields electromagnetic that are responsible for varying the angle of polarization when the observer tilts his head, getting in this way the polarization of the glasses always coincides in the programmed position with respect to the polarizations of the monitor regardless of the position taken by the observer, is say, upright, lying down or leaning.

The glasses pins incorporate some mini headphones that activate automatically when the 2D-Dual mode display and thus allows two groups of observers to see simultaneously two different programs or broadcasts throughout the extension of the screen, forcing two audio bands to differentiate, so both, the sound of the monitor speakers would be canceled and, at same time, the polarizers of the glasses or the polarizers of the liquid crystal would be oriented at the same angle in both eyes coinciding with the polarization of the monitor that emits the program chosen, indicating that when the 2D-Dual mode the image is flat.

Finally, it should be indicated that a mobile structure that allows the three-dimensional monitor to become in a conventional 2D monitor, and this mutation or change of structure and functionality is very useful when different structures and elements are part of a versatile environment or space.

Description of the drawings

To complement the description that is being performing and in order to help a better understanding of the characteristics of the invention, is accompanied herein descriptive, as an integral part of it, a set of planes in which with an illustrative and non-limiting nature, represented the following:

Figure number 1.- Represents a first embodiment of the invention in rest position relative to a procedure for manufacturing display monitors Stereoscopic

Figure number 2.- Reflects a view of the object shown in figure number 1 in position of utilization.

Figure number 3.- Corresponds to a second embodiment of the invention in rest position.

Figure number 4.- Corresponds to a view deployed from the object shown in figure number 3.

Figure number 5.- Reflects the object shown in figures 3 and 4 in use position.

Figure number 6.- Shows a third embodiment of the invention in rest position.

Figure number 7.- Shows the object represented in figure number 6 at a time of its mobilization.

Figure number 8.- Shows the object represented in figures 6 and 7 in position of use.

Figure number 9.- Corresponds to a fourth embodiment of the invention in rest position.

Figure number 10.- Represents the object reflected in figure number 9 in use position.
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Figure number 11.- Represents a fifth embodiment of the invention in rest position.

Figure number 12.- Reflects the object represented in figure number 11 in position of mobilization.

Figure number 13.- Corresponds to a view of the object represented in figures number 11 and 12 in position of use.

Figure number 14.- Represents a view in front and profile elevation of a support for viewing images without requiring the use of glasses.

Figure number 15.- Corresponds to a view in plan of the object reflected in figure number 14.

Figure number 16.- Shows a variation of the object shown in figures 14 and 15.

Figure number 17.- Corresponds to another embodiment of the invention.

Figure number 18.- Finally shows a front view of the object represented in figure number 17.

Preferred Embodiment of the Invention

Following the figures numbers 1 and 2 you can observe how monitors (1) and (2) are positioned in 90º angle, with the semi-plated glass attached to the monitor surface (2) to be incorporated later for diagonal use between monitors (1) and (2), such and as shown in figure number 2.

Figures 3, 4 and 5 show that the monitors (1) and (2) are located horizontally and adjacent among which is the semi-plated glass (3), being able to mobilize the monitor (2) until reaching 90º and position vertically, moving the semi-plated glass (3)  being diagonally between the monitors (1) and (2).

Figures 6, 7 and 8 show as monitors (1) and (2) are incorporated inside a piece of furniture (4), the monitor (1) standing vertically and in horizontal the monitor (2) on which the glass appears semiplateado (3) that can be located diagonally, and acting both monitors when the monitor (1) moves in direction vertical up to 90º in relation to the monitor (2).

Figures 9 and 10 show how the monitor (2), fixed to a support, is positioned vertically and the monitor (1) horizontally, adjacent to which the semi-plated glass (3), to subsequently mobilize the crystal  semiplateado (3) being diagonally allowing its utilization.

Figures 11, 12 and 13 show that monitors (1) and (2) are located vertically adjacent and between them is the semi-plated glass (3), to subsequently the monitor (1) is mobilized until it reaches 90º in relation to the monitor (2) being placed horizontally and, subsequently, the semi-plated glass (3) be diagonally allowing its use.

Figures 14, 15 and 16 show as from a base (10) emerges a support (11) from which they stand out adjacent elements (12) and (13) that can sneak off acting on replacing the glasses, presenting the object shown in figure number 16 a physical configuration differentiated but of application similar to the object reflected in the Figures numbers 14 and 15.

Figure 17 shows the monitor (20), the monitor (21) located at an angle of 90º, remaining positioned the monitor (20) horizontally and at the top and the monitor (21) vertically inside a structure of support (22) with a support structure (23) and a regulator (24) of inclination, placing the semi-plated glass (25) in diagonal between them.

Claims (11)

1. Procedure for the manufacture of stereoscopic display monitors, of those intended to adapt to the final polarization carried out by TFT-LCD monitors or any other type, characterized by being composed of two monitors with a 90º angular offset with respect to the final polarization that each one of them carries out, incorporating polarizers for the correction of angular offset different from 90º located in the glasses or in the frames that replace them, having polarizing filters in the stereoscopic cameras of recording or emission of images, placing a polarizer in the left chamber coinciding with the same polarization angle of the monitor that reproduces the image destined for the left eye or 90º offset in relation to the monitor that reproduces the image destined for the right eye, and a polarizer would be coupled to the right chamber coinciding with the polarization angle of the monitor in charge to reproduce the image for the right eye or 90º offset with respect to the monitor that generates the image for the eye
left. 2. Procedure for the manufacture of stereoscopic display monitors, according to the first claim, characterized by incorporating external polarizing frames for the visualization of the three-dimensional images generated by the monitors without the use of the glasses, composed of passive polarizers and polarization fields they can be composed of liquid crystals, which can change their polarization angle by electrically exciting one or both fields. 3. Procedure for the manufacture of stereoscopic display monitors, according to the first claim, characterized in that the glasses for three-dimensional visualization are provided with crystals or plastics with the offset angles similar to the frames formed by the bases (10 ), the support (11) and the display elements (12) and (13), presenting angular balancing-free means constituted by a small overweight in the lower part of each filter or filter support which, due to the force of gravity, mobilizes the filters and maintains the polarization angles in relation to the two polarization fields generated in the monitor. 4. Procedure for the manufacture of stereoscopic display monitors, according to the third claim, characterized in that the polarizing filters incorporated in the glasses can be replaced by liquid crystal polarizers managed by electromagnetic fields that would give the polarization angle. 5. Procedure for the manufacture of stereoscopic display monitors, according to the third claim, characterized in that the glasses are provided with the mini-headset headsets that are automatically activated when the 2D-Dual mode display is adopted. 6. Procedure for the manufacture of stereoscopic display monitors, according to the first claim, characterized in that the monitors (1) and (2) can be located at a 90 ° angle, the monitor (2) being positioned horizontally and the monitor (1) vertically, the semi-plated glass (3) being incorporated diagonally between them, moving from the surface of the monitor (2). 7. Procedure for the manufacture of stereoscopic display monitors, according to the first claim, characterized in that in a second embodiment the monitors (1) and (2) can be located horizontally and in parallel, between which the semi-plated glass is located ( 3), moving the monitor (2) until reaching verticality and positioning the semi-plated glass (3) diagonally. 8. Procedure for the manufacture of stereoscopic display monitors, according to the first claim, characterized in that in a third embodiment the monitors (1) and (2) can be located inside a piece of furniture (4), being in the rest position the semi-plated glass (3) on the surface of the glass (2), subsequently moving the monitor (1) in an upward vertical direction and incorporating the semi-plated glass (3) diagonally between the same monitors (1) and (2). 9. Procedure for the manufacture of stereoscopic display monitors, according to the first claim, characterized in that in a fourth embodiment the monitor (1) is placed horizontally and the monitor (2) vertically, the semi-plated glass (3) being adjacent to the surface of the monitor (1) until it moves diagonally being placed between them. 10. Procedure for the manufacture of stereoscopic display monitors, according to the first claim, characterized in that in a fifth embodiment the monitors (1) and (2) are placed vertically and in parallel and between them the semi-plated glass (3), moving the monitor (1) until it reaches an angle of 90º and the semi-plated glass (3) diagonally between them. 11. Procedure for the manufacture of stereoscopic display monitors, according to the first claim, characterized in that in a sixth embodiment the monitors (20) and (21) are incorporated into a support structure (22), provided with a structure (23) support and a tilt regulator (24), and the semi-plated glass incorporated diagonally between the monitors (20) and (21).