KR101210487B1 - Multipurpose 3Dimensional Stereo Glasses having capability for operating mode selection - Google Patents

Abstract

The present invention provides a three-dimensional image provided by an image display unit including a television receiver having an alternating display of an image for the right and an image for the left, and a projector for projecting the image for the right and the image for the left in turn. Claims [1] A multi-purpose three-dimensional glasses for viewing a light, comprising: a right lens and a left lens made of a liquid crystal operated in a shutter mode in which light transmission is interrupted or a polarization mode in which a polarization direction of transmitted light is changed; An operation selector configured to select an operation mode of the right lens and the left lens; A controller configured to control operations of the right lens and the left lens to be synchronized with operations of the image display unit; And a power supply unit supplying power required for the operation of the right lens and the left lens, the operation selection unit, and the control unit. It provides a three-dimensional glasses including, by adopting the liquid crystal capable of operating in the polarization mode and the shutter mode by the user's selection as the left lens and the right lens has an effect that can be used in both home and theater.

Description

Multipurpose 3Dimensional Stereo Glasses having capability for operating mode selection}

The present invention relates to a multi-purpose three-dimensional glasses, and more particularly, can be used as a shutter glasses, polarized glasses, and sunglasses glasses by the user's operation mode selection, when the power of the glasses is turned off (OFF) The present invention relates to a multi-purpose three-dimensional stereoscopic glasses capable of selecting a mode that can be used as general or non-degree general glasses.

Currently, technologies related to stereoscopic images such as stereoscopic television broadcasting, stereoscopic movies, and stereoscopic games are developing day by day in the digital age, and are in the process of being distributed to the public.

The reason for human perception of 3D space is because different images are incident through left and right eyes. Therefore, due to this principle, two images must be photographed in order to realize a stereoscopic image.

Therefore, at least two stereoscopic video cameras take images from different angles, separate them, and transfer them to the display to realize stereoscopic images.

There are two methods of viewing three-dimensional images: glasses and glasses-free glasses.

Among them, a method of wearing glasses is a polarization method using polarized glasses having different polarization directions, and a liquid crystal shutter eyeglass method (or time division) using glasses with a liquid crystal shutter that is periodically synchronized with a time-divided screen and synchronized with the period. Method).

Shutter-type stereoscopic glasses are generally used in smaller video facilities such as home TVs, and polarized stereoscopic glasses are generally used in large video facilities such as theaters.

When entering a theater for viewing a stereoscopic movie, the theater distributes the three-dimensional glasses to the audience, but most of the reusable glasses are disposable disposable glasses due to problems such as cleaning management and hygiene. As a result, environmental problems are raised, and various complex social problems are generated in the hygiene while reusing disposable glasses in order to violate regulations and save costs.

Experienced audiences want to use the three-dimensional glasses used in their homes for watching movies more stable, but there was a problem that it is difficult to use at the same time because they are three-dimensional glasses of different methods.

Therefore, the need for three-dimensional glasses that can be used at the same time at home and theater for movie viewing.

An object of the present invention is to provide a three-dimensional stereoscopic glasses and general sunglasses glasses that can be used in both home and theater by adopting the liquid crystal capable of operating in polarization mode and shutter mode by the user's selection as the left lens and the right lens. Another object of the present invention is to provide a versatile three-dimensional stereoscopic glasses capable of selecting a mode that can be used as general or non-degree general glasses when the stereoscopic glasses mode is not used.

In addition, the present invention is a multi-purpose three-dimensional stereoscopic capable of mode selection to cope with various stereoscopic imaging facilities according to the production company by adjusting the operating speed of the left and right lenses in accordance with the oscillation signal of the stereoscopic image signal that is different for each production company It is an object to provide glasses.

The present invention provides a three-dimensional image provided by an image display unit including a television receiver having an alternating display of an image for the right and an image for the left, and a projector for projecting the image for the right and the image for the left in turn. A three-dimensional glasses for viewing a light, comprising: a right lens and a left lens made of a liquid crystal operated in a shutter mode in which light transmission is interrupted or in a polarization mode in which a polarization direction of transmitted light is changed; An operation selector for selecting an operation mode of a right lens and the left lens; A controller configured to control operations of the right lens and the left lens to be synchronized with operations of the image display unit; And a power supply unit supplying power required for the operation of the right lens and the left lens, the operation selection unit, and the control unit. Provides a versatile three-dimensional stereoscopic glasses capable of mode selection including a.

The right lens and the left lens may further include a sunglasses mode in which the amount of light transmission is changed at the same time.

When the sunglasses mode is selected in the operation selection unit, the right lens and the left lens may further include a transmission amount adjusting unit for adjusting the light transmission amount.

The operation selector may cause the right lens and the left lens to operate in the polarization mode when the image display unit is a television receiver, and the right lens and the left lens to operate in the shutter mode when the image display unit is a projector.

When the right lens and the left lens operate in the polarization mode, the controller may control the polarization period of the right lens and the left lens to be synchronized with the polarization period of the right image and the left image displayed on the display. .

When the right lens and the left lens operate in the shutter mode, the control unit may alternately transmit light in synchronization with the right image and the left image projected by the right lens and the left lens to the image projector. Can be.

When the operation selection unit is turned off, the right and left lenses may be in a state in which light is transmitted.

The power supply unit may be a rechargeable battery.

The power supply unit may use a USB type connector.

The apparatus may further include a signal adjusting unit configured to adjust the driving signal of the liquid crystal.

The signal adjusting unit may adjust a frequency of the driving signal in response to the oscillation signal of the stereoscopic image signal of the image display unit which varies according to a production company.

The signal adjusting unit may continuously change the frequency of the driving signal.

The signal adjusting unit may change a frequency of the driving signal after selection by a user.

The present invention as described above has the effect that can be used in both home and theater by adopting the liquid crystal capable of operating in the polarization mode and the shutter mode by the user's selection as the left lens and the right lens.

In addition, when the power of the three-dimensional stereoscopic glasses is turned off (OFF) has the effect that can be used as a general frequency glasses or non-degree general glasses.

In addition, by adjusting the operating speeds of the left and right lenses according to the oscillation signals of the stereoscopic image signals that differ among the production companies, a multi-purpose three-dimensional glasses that can select a mode that can respond to various stereoscopic imaging facilities according to the production companies are provided. Has the effect.

1 is a perspective view showing the configuration of a multi-purpose three-dimensional glasses according to an embodiment of the present invention.
Figure 2 is a block diagram showing the configuration of a multipurpose three-dimensional glasses according to an embodiment of the present invention.
3 is a view for explaining the operation when the multi-purpose three-dimensional stereoscopic glasses according to an embodiment of the present invention operates in the polarization mode.
4 is a view for explaining the operation of the multi-purpose three-dimensional stereoscopic glasses in the shutter mode according to an embodiment of the present invention.

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

1 is a perspective view showing the configuration of a multi-purpose three-dimensional stereoscopic glasses according to an embodiment of the present invention, Figure 2 is a block diagram showing the configuration of a multi-purpose three-dimensional stereoscopic glasses according to an embodiment of the present invention.

Referring to FIGS. 1 and 2, the 3D stereoscopic glasses 100 according to the present invention may include a right lens 110a and a left lens 110b, an operation selector 120, a controller 130, and a power supply 150. Include.

First, an image display unit displaying a stereoscopic image will be described.

The video display unit includes a television receiver 10, a projector 20, and the like.

Let's look at this.

The television receiver 10 does not only mean a receiver for receiving an over-the-air TV broadcast, but includes all cases of receiving and displaying cable broadcasting, satellite broadcasting, and other Internet broadcasting. In addition, a video receiver such as a video cassette recorder (VCR) or a video information storage / playback device such as a digital video disk (DVD) or a video CD or a video game machine can be connected to a television receiver to display various types of images. This includes the display.

The cathode ray tube (CRT) method is generally used as the operation method of the television receiver, but other types of operation methods are included as long as the video signal is periodically scanned on the screen.

Here, the television receiver 10 also includes a monitor of a computer and a monitor for display of another information storage medium or system.

Here, the composite stereoscopic image signal provided by the television receiver 10 is a composite image signal obtained by multiplexing a left and right image signal photographed by two cameras of the subject, and the stereoscopic image signal is a memory of a PC, a CD ROM, It may be stored in a recording medium such as a DVD, a video tape, and the like, or may be directly received in real time, such as a TV video signal in real time, or downloaded and output through the Internet. Such a complex stereoscopic image signal can be reproduced by a polarization filter.

The display polarization filter 12 is attached to the front of the television receiver 10. The display polarization filter 12 operates corresponding to the left and right images provided by the television receiver. That is, when the left image is provided, the polarization is polarized in the same direction as the left lens 110b described later, and when the right image is provided, the polarization is polarized in the same direction as the right lens 110a described later.

It is preferable that the display polarizing filter 12 is detachably attached to the front of the television receiver 10. The detachable means of the polarization filter 12 may be variously selected according to the needs of the user.

The image display unit may include a projector 20. The projector 20 is a type of device that enlarges an image signal captured on a film with a projection lens or the like and projects it onto the front or the back of the projection screen 30, and is used in a movie theater or the like. The stereoscopic image signal captured by the film alternately flashes left and right images captured by two cameras at a predetermined signal period, and is provided to the user.

In addition, the projector 20 includes an image projector for projecting the image formed by receiving the image signal to the front or rear of the screen by enlarging the image formed by a projection lens or the like.

3D stereoscopic glasses 100 according to an embodiment of the present invention, the right lens 110a and the left lens 110b is fixed to both sides of the glasses body 102, as shown in the figure, for stable wearing Right and left eyeglasses (104a, 104b) is a structure that spans the user's ear, the same shape as the general eyeglasses, a detailed description thereof will be omitted.

Liquid crystal is used as the material of the right lens 110a and the left lens 110b of the three-dimensional stereoscopic glasses 100. The liquid crystal used in the present invention may operate in a shutter mode that becomes transparent or opaque by a control signal applied from the outside and a polarization mode that transmits only vertically or horizontally polarized light by a control signal applied from the outside. In addition, the right lens 110a and the left lens 110b may simultaneously operate in a sunglasses mode that is opaque at a predetermined concentration. Since the configuration of the liquid crystal is a well-known technique, a detailed description thereof will be omitted.

The liquid crystal may be formed in a circular shape like a general spectacle lens, and may be formed in various shapes according to the shape of the 3D stereoscopic glasses 100 or other tastes of the user.

Meanwhile, the liquid crystal used as the right lens 110a and the left lens 110b maintains a transparent state when a signal applied from the outside is turned off. At this time, the three-dimensional stereoscopic glasses 100 can be used as a general vision correction glasses. That is, if the front and rear surfaces of the right lens 110a and the left lens 110b made of liquid crystal are formed to have a predetermined curvature to serve as a concave lens or a convex lens, the multipurpose three-dimensional stereoscopic glasses according to the present invention are powered off. City can be used as general power glasses for vision correction. In addition, if the front and rear surfaces of the right lens 110a and the left lens 110b are formed flat, it can also be used as a normal glasses.

The right lens 110a and the left lens 110b may be alternately operated by the controller 130 to be described later. A detailed description thereof will be given later.

The operation selector 120 sets an operation state of the right lens 110a and the left lens 110b to a shutter mode or a polarization mode. The operation selector 120 may be configured as a slide switch or a rotary switch to select a connection terminal. In addition, the operation selector 120 may be attached to the right or left eyeglasses 104a and 104b and adjusted by a user's selection. In addition, the television receiver 10 or the projector 20 may be configured to receive wirelessly information about the operation mode.

The operation selector 120 is connected to the controller 130 described later by a signal line.

The controller 130 applies a predetermined signal corresponding to each operation mode to the right lens 110a and the left lens 110b in which the operation mode is set by the operation selector 120, thereby applying the right lens 110a and the left lens. Allow 110b to operate.

The operation of the right lens 110a and the left lens 110b by the controller 130 will be described.

According to FIG. 1, an operation selector 120, a controller 130, and a signal adjuster 140 are installed in the right glasses leg 104a, and a power supply 150 is installed in the left glasses leg 104b. As an example of installation, the installation location may be changed in various ways depending on the needs of the user.

3 is a view for explaining the operation when the multi-purpose three-dimensional stereoscopic glasses according to an embodiment of the present invention operates in the polarization mode.

Referring to FIG. 3, when the polarization mode is selected by the operation selector 120, the operations of the right lens 110a and the left lens 110b by the controller 130 are as follows. In the drawings, the three-dimensional stereoscopic glasses 100 are briefly illustrated for simplicity of the drawings.

In this case, the polarization mode is selected when the television receiver 10 operates as an image display unit.

Here, the right lens 110a, the left lens 110b, and the display polarizing filter 12 all have a function of transmitting only linearly polarized light in the horizontal direction, that is, assumed to be a linear polarizer fixed in the horizontal direction. This will be described.

Referring to the case in which the image for the left eye is displayed on the television receiver 10, first, an image directed from the screen of the television receiver 10 toward the display polarization filter 12 is transmitted only if the linear polarization direction of light is a horizontal component. . In addition, since the voltage is not applied to the left lens 110b, since the linearly polarized light is transmitted in the horizontal direction as it is, the left eye of the user can see the left eye image well.

When the left eye image displayed on the display screen enters the right eye, the image passing through the display polarization filter 12 has a linear polarization direction of light as in the case of the left eye. However, since a voltage is applied to the right lens 110a by the instantaneous driving device, the linear polarization direction of the light changes in the vertical direction while passing through the right lens 110a.

Since the light output through the display polarization filter 12 cannot pass through the right lens 44 polarized in the horizontal direction, the right eye cannot see the left eye image.

When the right eye image is displayed on the display screen, the left eye cannot see the right eye image because the polarization direction of light transmitted through voltage is applied to the left lens 110b is changed in the vertical direction. Therefore, the left eye can always see only the left eye image and the right eye can always see only the right eye image, so that the user can feel a stereoscopic image.
In more detail, the controller 130 applies a predetermined signal to the right lens 110a and the left lens 110b so that the right lens 110a and the left lens 110b alternately operate. That is, the left lens 110b and the right lens 110a are alternately linearly polarized by signals applied from the controller 130.
That is, when the left eye image is provided by the television receiver 10, the left lens 110b is in a linearly polarized state in the horizontal direction, and the right lens 110a is in a linearly polarized state in the vertical direction. You will only see the Dragon image.
Then, when the right image is provided by the television receiver 10, the right lens 110a is in a linearly polarized state in the horizontal direction, and the left lens 110b is in a linearly polarized state in the vertical direction. You will only see the Dragon image.
At this time, the polarization direction change operation of the left lens 110b and the right lens 110a are displayed alternately, and the operation period in which the polarization direction in which the operation is switched is changed is made within a time that is unknown to the user.
As the user views the left and right images alternately, the user can view the stereoscopic image.

In the above embodiment, only the case where the polarization filter 12, the right lens 110a and the left lens 110b are linearly polarized in the horizontal direction has been described as an example, but the present invention is not limited only to the case. The case where the polarization filter 12, the right lens 110a and the left lens 110b are linearly polarized in the vertical direction is also within the scope of the present invention.

In addition, when the linear polarization directions of the polarization filter 12, the right lens 110a and the left lens 110b are changed in the same manner at a predetermined angle other than vertical or horizontal, or when the light is slightly modified or changed to produce the same effect. Also within the scope of the present invention will be appreciated by those skilled in the art.

4 is a view for explaining the operation of the multi-purpose three-dimensional stereoscopic glasses in the shutter mode according to an embodiment of the present invention.

Referring to FIG. 4, when the shutter mode is selected by the operation selector 120, the operations of the right lens 110a and the left lens 110b by the controller 130 are as follows.

In this case, the shutter mode is selected when the projector 20 operates as an image display unit. The projector 20 provides a stereoscopic image in such a manner that the images of the left and right images are alternately projected on the screen 30.

Reference numeral 22, not shown, is a projection lens that enlarges and projects an image on the screen 22. Since a configuration and method for providing a stereoscopic image on a film by a projector is a known technique, a detailed description thereof will be omitted.

The controller 130 applies a predetermined signal to the right lens 110a and the left lens 110b so that the right lens 110a and the left lens 110b alternately operate. That is, the opaque and transparent states of the left lens 110b and the right lens 110a are alternately displayed by signals applied from the controller 130. In more detail, when the left image is provided by the projector 20, the left lens 110b becomes transparent, and the right lens 110a becomes opaque, and the user sees only the left image. .

When the right image is provided by the projector 20, the right lens 110a becomes transparent, and the left lens 110b becomes opaque, and the user sees only the right image.

At this time, the operation of the left lens 110b and the right lens 110a alternately appear, and the operation is switched within a time that is too fast for the user to know.

As the user views the left and right images alternately, the user can view the stereoscopic image.

Here, the signal controller 140 is connected to the controller 130. The signal adjusting unit 140 may set operation cycles of the left lens 110b and the right lens 110a. That is, the operation period of the left lens 110b and the right lens 110a may be preset to a predetermined value, but the period of providing the left image and the right image provided by the projector or the monitor according to the manufacturer (flashing cycle) Or the polarization direction change period) may be changed.

In order to overcome this, the signal adjusting unit 140 may change the operation cycles of the left lens 110b and the right lens 110a. At this time, the signal adjusting unit 140 is composed of a variable resistor and the adjustment knob to continuously change the operation cycle and to synchronize the operation cycle of the right lens (110a) and the left lens (110b) to the operation period of the projector or the monitor.

In addition, the signal adjusting unit 140 may be configured to be selected by a user's selection switch operation after storing the provision periods of the left image and the right image of the projector or monitor according to the manufacturer.

In this case, the sunglasses mode may be selected by the operation selector 120. In the sunglasses mode, the left lens 110b and the right lens 110a simultaneously control the degree of light transmission at the same concentration, thereby allowing the three-dimensional stereoscopic glasses 100 according to the present invention to be used as sunglasses. The concentration of the left lens 110b and the right lens 110a can be set according to the needs of the user.

On the other hand, when the operation selection unit 120 is set to the off state, that is, when no monitor or projector is used, the right lens 110a and the left lens 110b maintain the transparent state. At this time, if the front and rear of the left lens (110b) and the right lens (110a) is formed with a predetermined curvature, the three-dimensional stereoscopic glasses 100 according to the present invention can be used as glasses for general vision correction rather than three-dimensional glasses Can be.

The power supply unit 150 supplies power for the operation of the left and right lenses 110a, the operation selection unit 120, and the controller 130. The power supply unit 150 may be formed of a rechargeable battery attached to one side of the left eyeglasses leg 104b for stable power supply. Here, when the power available from the power supply unit 150 has been consumed, it may be connected to an external power input terminal for charging. Here, the power supply unit 150 preferably includes a USB charging terminal 160 for ease of charging.

The present invention configured as described above can enjoy a stereoscopic image in the home and theater with the same three-dimensional glasses.

In addition, when the operation cycle is different according to the production company of the home television, it is possible to enjoy the stereoscopic image by adjusting the operation of the stereoscopic glasses in response thereto.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

100: three-dimensional glasses
110a: right lens
110b: left lens
120: motion selection unit
130:
140: signal adjustment unit
150:

Claims (11)

You can watch a three-dimensional image provided by a television receiver including an image for displaying the right image and the image for the left, and a projector for projecting the image for the right side and the image for the left side alternately. In the three-dimensional glasses to
A right lens and a left lens made of a liquid crystal operated in a shutter mode in which light transmission is interrupted or in a polarization mode in which a polarization direction of transmitted light is changed;
An operation selector for selecting an operation mode of a right lens and the left lens;
A controller configured to control operations of the right lens and the left lens to be synchronized with operations of the image display unit; And
A power supply unit supplying power required for the operation of the right lens and the left lens, the operation selection unit, and the control unit;
Containing
Versatile 3D glasses with selectable modes. The method of claim 1,
The right lens and the left lens at the same time further comprises a sunglasses mode in which the degree of light transmission is equally limited
Versatile 3D glasses with selectable modes. The method of claim 1,
The operation selector
If the image display unit is a television receiver, the right lens and the left lens are operated in the polarization mode.
If the image display unit is a projector to operate the right lens and the left lens in the shutter mode,
Versatile 3D glasses with selectable modes. The method of claim 3,
When the right lens and the left lens are operated in the polarization mode
The control unit
An operation period in which the polarization directions of the right lens and the left lens are changed is controlled to be synchronized with a provision period of the right image and the left image displayed on the display.
Versatile 3D glasses with selectable modes. The method of claim 3,
When the right lens and the left lens are operated in the shutter mode
The control unit
The right lens and the left lens alternately transmits light in synchronization with the right image and the left image projected by the image projector.
Versatile 3D glasses with selectable modes. The method of claim 3,
When the operation selection unit is off
The right lens and the left lens is a state in which light is transmitted
Versatile 3D glasses with selectable modes. The method of claim 1,
The power supply unit is a rechargeable battery
3-D stereoscopic glasses with selectable modes. The method of claim 7, wherein
The power supply unit uses a USB type connector
Versatile 3D glasses with selectable modes. The method of claim 1,
Further comprising a signal adjusting unit for adjusting the drive signal of the liquid crystal,
The signal adjusting unit is a multi-purpose three-dimensional glasses of the mode can be selected to adjust the operation period of the right lens and the left lens in response to the period of providing the stereoscopic image of the image display unit. 10. The method of claim 9,
The signal adjusting unit is a multi-purpose three-dimensional glasses that can be selected in the mode of continuously changing the operation period. 10. The method of claim 9,
The signal adjusting unit is a multi-purpose three-dimensional glasses that can select the mode to change by the user's selection after setting the operation period.

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