KR20020021427A - Apparatus for remote driving of 3D picture glasses - Google Patents

Abstract

PURPOSE: A wireless driver for stereoscopic image spectacles is provided to simultaneously see a stereoscopic image by a plurality of wire/wireless users by automatically changing an image by an interlaced scanning method. CONSTITUTION: A modulation frequency generator(202) frequency-modulates an LCD shutter drive signal of stereoscopic image spectacles from a signal input monitor(118). An infrared ray transmitter modulates a vertical sync signal divided by a vertical sync signal divider(116) to an infrared ray sync signal. A high frequency transmitter(220) modulates the vertical sync signal to a high frequency sync signal according to a modulation frequency from the modulation frequency generator(202). Infrared ray stereoscopic image spectacles(218) receives an infrared signal from an infrared ray generator(210) and drive left and right LCD shutters. High frequency stereoscopic image spectacles(226) receive the high frequency sync signal from the high frequency transmitter(220) and drive the left and right LCD shutters. A voltage regulator(106) supplies necessary powers to each part.

Description

Wireless driving device for stereoscopic image glasses {Apparatus for remote driving of 3D picture glasses}

The present invention relates to an apparatus for implementing a stereoscopic image, and more particularly, to a stereoscopic image for convenience of use, by wirelessly driving a stereoscopic image glasses for realizing a stereoscopic display of a screen displayed on a CRT monitor in a computer system. The present invention relates to a wireless driving device of the image glasses.

In general, the basic principle of the technology for realizing stereoscopic images is to show a sense of unity by showing different visual images to the left and right eyes of a person. Each stereoscopic image is two images taken at the visual position of the left and right eyes, respectively. Consists of

In the conventional stereoscopic image implementation technology, a stereoscopic image has been realized by synthesizing the two left and right eye images as described above and outputting the image signal to a CRT monitor. As a representative output method of such a stereoscopic image, there is an interlaced output method in which a left or right eye image is alternately displayed only on even or odd scan lines for each field displayed on a CRT monitor by applying an interlaced scanning method of a CRT monitor.

In the case of displaying a stereoscopic image on a CRT monitor in the above-described manner, conventionally, left and right eye images are inserted by separately inserting a control program for controlling a computer graphics board in a computer program to display the CRT monitor in an interlaced scanning method. The synthesized stereoscopic images have been displayed on the monitor.

However, the above-described method has a problem in that a separate control program is required due to the difference between the types of graphics cards and the characteristics of each graphics resolution mode. There are difficulties in developing such a control program, and many of them are impossible, and there is another problem in that the control program is not compatible with different computer models, and thus a control program must be made for each computer and model. .

In addition, since the three-dimensional image driving device and the three-dimensional image glasses are connected by a wire, there is a limit to the use distance, there was an inconvenience to move the line together when wearing the three-dimensional image glasses.

The present invention is to solve the above-mentioned problems of the prior art, the object is to install a scanning line control unit between the computer graphics board and the input of the salty monitor to automatically change the image to interlaced scanning method, The present invention provides a wireless driving apparatus for stereoscopic glasses, which enables a plurality of wired and wireless users to simultaneously view stereoscopic images because they are driven by wires as well as wirelessly.

1 is a connection configuration diagram of a wireless driving device of the three-dimensional image glasses according to an embodiment of the present invention,

2 is a block diagram of a wireless driving device for stereoscopic image glasses according to an embodiment of the present invention.

<Description of Symbols for Major Parts of Drawings>

100: computer graphics card 101: three-dimensional image control device

102, 104: first and second shock absorber 103: remote control device

105: power switch 106: constant voltage portion

108: DC-DC converter 110: video signal controller

112: Sialty monitor 114, 116: Horizontal, vertical sync signal divider

118: signal input monitor 120: vertical blank signal detector

122: glasses driving unit 124, 126: left, right LCD shutter

128: glasses driving frequency generator 210: infrared transmitter

212: infrared synchronization signal modulator 214: infrared modulation signal amplifier

216: infrared light emitting unit 218: infrared stereoscopic image glasses

220: high frequency transmitter 222: RF synchronous signal modulator

224: RF modulation signal amplifier 226: high frequency stereoscopic image glasses

In order to achieve the object of the present invention, a wireless driving device for stereoscopic image glasses according to the present invention is a sitity monitor displaying image data driven by a computer on a screen, and is perpendicular to the R, G, and B image data output from the computer. Computer graphics card for outputting the horizontal / horizontal synchronization signal, a vertical synchronization signal divider for dividing the vertical synchronization signal output from the computer graphics card by 1/2, and a vertical / horizontal synchronization signal output from the computer graphics card, A stereoscopic image forming apparatus including a signal input monitor for generating an LCD shutter driving signal of an image glasses, comprising: a modulation frequency generating means for frequency modulating and outputting an LCD shutter driving signal of the stereoscopic image glasses output from the signal input monitor; Modulation outputted from the modulation frequency generating means by the vertical synchronizing signal divided by the vertical synchronizing signal divider Infrared transmitting means for modulating and transmitting the infrared synchronizing signal according to the wave number, and vertical synchronizing signal divided by the vertical synchronizing signal divider is modulated into a high frequency synchronizing signal according to the modulation frequency output from the modulating frequency generating means to generate a high frequency signal. High frequency transmitting means for transmitting, Infrared stereoscopic image glasses for driving the left and right LCD shutter by receiving the infrared signal output from the infrared transmitting means wirelessly, Left and right eye receiving the high frequency radio signal transmitted from the high frequency transmitting means Characterized in that it comprises a high-frequency stereoscopic glasses driving the LCD shutter.

Herein, the infrared transmitting means includes infrared modulating means for modulating the vertical synchronizing signal divided by the vertical synchronizing signal divider into an infrared synchronizing signal according to the modulation frequency output from the modulating frequency generating means, and the infrared synchronizing means outputted from the infrared modulating means. And an infrared light emitting unit for generating infrared rays according to the infrared modulation signal amplified and output by the infrared amplifying unit.

In addition, the high frequency transmitting means includes a high frequency modulating means for modulating the vertical synchronizing signal divided by the vertical synchronizing signal divider into a high frequency synchronizing signal according to the modulation frequency output from the modulating frequency generating means, and the high frequency output from the high frequency modulating means. A high frequency modulated signal amplification unit for amplifying a predetermined level of the modulated signal and outputs through the antenna.

The present invention made as described above will be described in detail with reference to the accompanying drawings.

1 is an external connection configuration diagram of a wireless driving apparatus for stereoscopic glasses according to an embodiment of the present invention, which is inserted into an expansion slot of a computer to output an image signal and a computer graphics card ( A stereoscopic image control device 101 for switching the R, G, and B analog image signals outputted from 100) according to the scanning line mode to display on a monitor and generating a stereoscopic image driving signal for driving stereoscopic glasses; Power switch 105 for switching the operation of the control device 101, three-dimensional mode conversion switch (SW1) for switching three-dimensional mode, switching switch (SW2) for switching left and right images, infrared to wirelessly drive the three-dimensional image glasses Remote control device 103 including a generator and a high frequency antenna, and stereoscopic glasses (107) connected to the remote control device 103 by wire to drive the LCD shutter according to the stereoscopic image driving signal (107). And infrared or high frequency stereoscopic image glasses 218 and 226 for driving an LCD shutter (not shown) according to the high frequency or infrared wireless stereoscopic image driving signal output from the remote control device 103.

2 is a block diagram of a wireless driving apparatus for stereoscopic image glasses according to an embodiment of the present invention. As shown in FIG. 2, a ciali monitor 112 displaying image data driven by a computer on a screen, and the computer The computer graphics card 100 that outputs the R / G and B analog video signal vertical / horizontal synchronization signals outputted from the computer graphics card 100 and the analog video signal output from the graphics board 100 according to the input vertical / horizontal synchronization signal. A first signal buffering unit configured to display the image signal controller 110 displayed on the cialty monitor 112 and the horizontal synchronous signal H-sync and the vertical synchronous signal V-sync output from the computer graphics card 100, respectively. A horizontal / vertical sync signal divider 114 for dividing each of the vertical / horizontal sync signals output from the second buffers 102 and 104 and the first and second buffers 102 and 104, respectively. 116 and the vertical output from the second buffer 104 A signal input monitor 118 for detecting whether the synchronous signal V-sync is driven, and a glasses drive frequency generator for generating an image stereoscopic driving frequency according to whether the signal input monitor 118 detects a vertical synchronization signal ( And the left and right LCD shutters 124 and 125 of the stereoscopic image glasses connected by wires by the output signal of the spectacle driving frequency generator 128 and the vertical synchronizing signal from the vertical synchronizing signal divider 116. A glasses driver 122 for driving a light source, an image switching switch SW2 for controlling left and right eye images by controlling the glasses driver 122, the horizontal synchronous signal divider 114, and a vertical synchronous signal divider ( The stereoscopic image switch SW1 for switching the stereoscopic image signal driving signal to the image signal controller 110 according to each synchronization signal output from the 116 and the vertical synchronizing signal V output from the second buffer 104. -sync) to detect the vertical blank signal. A vertical blank signal monitor 120, a modulation frequency generator 202 for frequency modulating and outputting an LCD shutter driving signal of the stereoscopic image glasses output from the signal input monitor 118, and the vertical synchronous signal divider 116 Infrared transmission unit 121 and the vertical synchronous signal divider 116 to modulate the vertical synchronization signal divided by the infrared synchronization signal according to the modulation frequency output from the modulation frequency generator 202 and the vertical synchronization signal divider 116 A high frequency transmitter 220 for modulating a vertical synchronization signal divided by the high frequency synchronization signal according to the modulation frequency output from the modulation frequency generator 202 and transmitting the high frequency synchronization signal at high frequency; Infrared stereoscopic image glasses 218 for driving left and right LCD shutters (not shown in the drawing) by receiving infrared signals and high and low frequency signals output from the high frequency transmitter 220 to receive left and right L. And a high frequency stereoscopic image glasses 226 for driving a CD shutter (not shown in the figure), a constant voltage unit 106 and a DC-DC converter 108 for supplying the necessary power to each unit.

Here, the infrared transmitter 210 modulates the vertical synchronous signal divided by the vertical synchronous signal divider 114 into an infrared synchronous signal according to the modulation frequency output from the modulation frequency generator 202. 212, an infrared amplifier 214 for amplifying a predetermined level of the infrared modulated signal output from the infrared modulator 212, and infrared rays generated according to the infrared modulated signal amplified and output by the infrared amplifier 214. Infrared light emitting unit 216.

In addition, the high frequency transmitter 220 modulates the vertical synchronous signal divided by the vertical synchronous signal divider 116 into a high frequency synchronous signal according to the modulation frequency output from the modulation frequency generator 202. A modulator 222 and an RF modulated signal amplifier 224 for amplifying a high frequency modulated signal output from the RF synchronous signal modulator 222 through a antenna ANT.

When described in more detail with reference to Figures 1 and 2 attached to the operation according to the embodiment of the present invention configured as follows.

First, the R, G and B analog video signals output from the computer graphics card 100 and the horizontal / vertical synchronization signals passing through the first and second buffers 102 and 104 are input to the video signal controller 110. The image is displayed on the cialty monitor 112 through.

When the user views a stereoscopic image, the stereo mode conversion switch SW1 is turned on. The horizontal and vertical synchronizing signals divided into 1/2 through the horizontal and vertical synchronizing signal dividers 114 and 116 are exclusively ORed and applied to the image signal controller 110. The left eye video signal or the right eye video signal is alternately displayed only in odd or even scan lines in each field.

On the other hand, by detecting the output of the vertical synchronization signal from the second shock absorber 104 to drive the spectacle driving frequency generator 128, the spectacle driving unit is operated according to the driving frequency generated by the spectacle driving frequency generator 128. . The spectacle driving unit 122 drives the left and right LCD shutters 124 and 126 in accordance with the vertical synchronization signal output from the vertical synchronization signal divider 116.

While driving the left and right LCD shutters 124 and 126 of the wired stereoscopic image glasses wired through the glasses driving frequency generator 128 by the vertical synchronization signal divided by the vertical synchronization signal divider 116, wireless Driving the three-dimensional image glasses, the operation will be described in more detail as follows.

In order to drive the infrared and high frequency stereoscopic image glasses 218 and 226, first, the modulation frequency generator 202 receives a signal output from the signal input monitor 118 and generates a modulation frequency to generate an infrared synchronous signal modulator ( 212 and RF synchronization signal modulator 222, respectively.

The infrared synchronous signal modulator 212 modulates the synchronous signal for driving the stereoscopic image glasses by the modulation frequency output from the modulation frequency generator 202, and then applies the infrared synchronous signal modulator 214 to a predetermined level. Amplify. The infrared light emitting unit 216 is operated by the amplified infrared modulation signal. The infrared signal transmitted through the infrared light emitter 216 is input to an infrared receiver (not shown) of the infrared stereoscopic glasses 218 to drive the left and right LCD shutters (not shown) of the stereoscopic glasses. Let's do it.

If the user uses the high-frequency stereoscopic image glasses 226, the RF synchronization signal modulator 222 modulates the vertical synchronization signal divided by half through the vertical synchronization signal divider 116 to the modulation frequency generator 202. After modulating by the high frequency signal output from the RF modulated signal amplifier 224 is applied. The RF modulated signal amplifying unit 224 amplifies a predetermined level of the RF modulated signal and transmits it to the air through the antenna ANT.

The stereoscopic image glasses 226 equipped with an RF receiver (not shown) demodulate the RF modulated signal transmitted through the antenna ANT to perform left and right LCD shutters (not shown) of the stereoscopic image glasses, respectively. Drive it.

As the left and right LCD shutters are driven by the driving signal, the left and right LCD shutters are alternately driven, and the images displayed on the Sialty monitor 112 are displayed in three dimensions through the left and right LCD shutters.

As described above, the wireless driving device of the three-dimensional image glasses according to the present invention can eliminate the limitation and inconvenience of the use distance by driving the three-dimensional image glasses by infrared or high frequency (RF) wirelessly by wire. In addition, by simultaneously driving the wired and wireless, there is an effect that a plurality of users wearing wired or wireless stereoscopic glasses can enjoy stereoscopic images at the same time.

Claims (4)

A sity monitor for displaying image data driven by a computer on a screen, a computer graphics card for outputting R, G, B image data and vertical / horizontal synchronization signals output from the computer, and a vertical output from the computer graphics card. Vertical sync signal divider for dividing sync signal 1/2, signal input monitor for detecting LCD shutter drive signal of stereoscopic glasses by detecting vertical / horizontal sync signal output from computer graphic card, and wired connection to glasses driver In the stereoscopic image realization apparatus including a wired stereoscopic image glasses to be driven, Modulation frequency generating means for frequency modulating and outputting an LCD shutter driving signal of the stereoscopic image glasses output from the signal input monitor; Infrared transmitting means for modulating and transmitting the vertical synchronizing signal divided by the vertical synchronizing signal divider into an infrared synchronizing signal according to the modulation frequency output from the modulation frequency generating means; High frequency transmitting means for modulating a vertical synchronizing signal divided by the vertical synchronizing signal divider into a high frequency synchronizing signal according to a modulation frequency output from the modulation frequency generating means and transmitting the high frequency synchronizing signal at high frequency; Infrared stereoscopic image glasses for wirelessly receiving an infrared signal output from the infrared transmitting means to drive left and right LCD shutters; And And a high frequency stereoscopic glasses for driving left and right LCD shutters by receiving high frequency wireless signals transmitted from the high frequency transmitting means. The wireless driving apparatus of claim 1, wherein the wired stereoscopic image glasses, the infrared stereoscopic image glasses, and the high frequency stereoscopic image glasses are driven simultaneously by the same vertical synchronization signal. 2. The apparatus of claim 1, wherein the infrared transmitting means comprises: infrared modulating means for modulating a vertical synchronizing signal divided by the vertical synchronizing signal divider into an infrared synchronizing signal according to a modulation frequency output from a modulation frequency generating means; An infrared amplifying unit which amplifies a predetermined level of the infrared modulated signal output from the infrared modulating means; And And an infrared light emitting unit for generating infrared rays according to the infrared modulated signal amplified by the infrared amplifying unit. 2. The apparatus of claim 1, wherein the high frequency transmitting means comprises: high frequency modulating means for modulating a vertical synchronizing signal divided through the vertical synchronizing signal divider into a high frequency synchronizing signal according to a modulation frequency output from a modulating frequency generating means; And And a high frequency modulated signal amplifying unit configured to amplify a predetermined level of the high frequency modulated signal output from the high frequency modulating means and transmit the same through an antenna.