KR20130040275A - 3d emitter module and 3d synchronous signal system - Google Patents

Abstract

PURPOSE: A 3D emitter module and a 3D synchronization signal system thereof are provided to secure compatibility between 3D glasses and a 3D display device having a different protocol from the 3D glasses. CONSTITUTION: A formatter(120) detects and analyzes a 3D video signal received in a receiving unit(110) to generate a 3D synchronization signal synchronized with the 3D video signal. A first MCU(Micro Controller Unit)(140) receives and detects the 3D video signal by controlling the formatter and the receiving unit. A transmitting unit(130) outputs the 3D video signal of the formatter to the outside. An IR(Infrared Ray) modulating unit(160) modulates the 3D synchronization signal into an IR signal. A second MCU(150) transmits the 3D video signal by controlling the transmitting unit and the formatter and generates the 3D synchronization signal. [Reference numerals] (110) Receiving unit; (120) Formatter; (130) Transmitting unit; (160) IR modulating unit; (AA,BB) 3D video; (CC) First 3D synchronization signal; (DD) Second 3D synchronization signal;

Description

3D emitter module and 3D sync signal system {3D EMITTER MODULE AND 3D SYNCHRONOUS SIGNAL SYSTEM}

The present invention relates to a 3D emitter module and a 3D sync signal system, and more particularly, to analyze a video frame of a video signal input through an HDMI port of a 3D player device, and to generate and transmit a 3D sync signal through the system. It is about.

Recently, display technologies have been developed to realize stereoscopic (3D) images using binocular disparity.

A stereoscopic image system for implementing a stereoscopic image has been developed in various ways, such as a technique for viewing a stereoscopic image using polarized glasses or shutter glasses or a technique for viewing a stereoscopic image in a non-glasses state.

Among these, the stereoscopic imaging system using the shutter glasses has a configuration in which the shutter glasses receive an emitter signal transmitted in an infrared manner and the shutter glasses are operated by the emitter signal.

That is, the shutter glasses are operated by opening the left eye shutter when the left image is projected on the display device and opening the right eye shutter when the right image is projected. Accordingly, the viewer can view a stereoscopic image by binocular parallax.

The shutter glasses described above must be driven in accordance with the characteristics of the 3D display device while accurately synchronizing with the 3D display device in order to view a high quality stereoscopic screen.

That is, the 3D display device for displaying a stereoscopic image and the shutter glasses, which are stereoscopic glasses, must be driven in synchronization. In order to achieve synchronization, a 3D emitter for transmitting a synchronization signal (IR signal) to the 3D display apparatus is provided. It is provided.

However, 3D TVs, 3D projectors, etc. among the 3D display devices are incompatible by 3D display devices using different protocols by manufacturers.

Therefore, users need to have stereoscopic glasses for each manufacturer of the 3D display device in order to view a stereoscopic image, and thus the cost increases, and there is a complexity of storing and managing a plurality of stereoscopic glasses. There is an inconvenience to find and wear glasses.

In addition, from the manufacturer's point of view, a 3D emitter must be provided in the 3D display device, thereby increasing the unit cost of the product.

In addition, when a separate 3D transceiver is connected to a general TV among 3D display devices, a 3D ready TV or a 3D monitor capable of viewing 3D images may not be provided with the 3D emitter and a user must purchase it separately.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and analyzes a video frame of a video signal input through an HDMI port of a 3D player device, and generates and transmits and transmits a 3D sync signal through the 3D player device. Compatibility between 3D display devices can be ensured, and one 3D player device can be used to view stereoscopic images on various 3D display devices (eg, 3D TVs, 3D projectors, 3D Ready TVs or 3D monitors). The purpose is to provide a 3D emitter module and a 3D synchronization signal system.

In addition, another object of the present invention is to provide a 3D emitter module and a 3D synchronization signal system that can reduce the cost and convenient storage and management of the stereoscopic glasses by not having to purchase stereoscopic glasses for each manufacturer by ensuring the compatibility from the user's point of view. Its purpose is to.

Still another object of the present invention is to provide a 3D emitter module and a 3D synchronization signal system that can reduce the unit cost of a product by not having a 3D emitter when manufacturing a 3D display device from a manufacturer's point of view.

According to an aspect of the present invention, there is provided a 3D emitter module, including: a receiver configured to receive an external 3D video signal and output the same to a formatter;

A formatter for detecting and analyzing the 3D video signal and generating a 3D synchronization signal synchronized with the 3D video signal based on the analysis result;

A first MCU controlling the receiver and the formatter to receive and detect a 3D video signal;

A transmitter for outputting the 3D video signal of the formatter to the outside;

An IR modulator for modulating the 3D synchronization signal into an IR signal and transmitting the IR signal to an external device through an infrared communication method; And

And a second MCU to control the formatter and the transmitter to transmit 3D video signals and generate 3D synchronization signals.

In addition, the 3D synchronization signal system according to the present invention includes the 3D emitter module;

A 3D player device which is an external input device for inputting an external 3D video signal to the receiving unit;

A 3D display device for receiving a 3D video signal output from the transmitter and outputting a stereoscopic image; And

And an active stereoscopic glasses that open and close the left and right eye shutter lenses according to the 3D synchronization signal transmitted from the IR modulator.

According to the above-mentioned means for solving the problem, it is possible to ensure compatibility between 3D display devices having different protocols from stereoscopic glasses, and to view stereoscopic images through various 3D display devices using one 3D player device.

In addition, from the user's point of view, there is no need to purchase stereoscopic glasses for each manufacturer, thereby reducing costs and convenient storage and management of stereoscopic glasses.

In addition, the manufacturer does not need to provide a 3D emitter when manufacturing the 3D display device, thereby lowering the unit cost of the product.

1 is a block diagram of a 3D emitter module according to the present invention.
2 is a block diagram of a 3D synchronization signal system according to the present invention.
3 is a detailed block diagram of the stereoscopic glasses shown in FIG. 2.

Hereinafter, the configuration and operation of the present invention will be described with reference to the accompanying drawings.

However, the drawings and the following description shown below are for the preferred method among various methods for effectively explaining the features of the present invention, the present invention is not limited only to the drawings and description below. In addition, in the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. In addition, terms to be described below are terms defined in consideration of functions in the present invention, which may vary according to a user's or operator's intention or custom. Therefore, the definition should be made based on the contents throughout the present invention.

As a result, the technical spirit of the present invention is determined by the claims, and the following examples are one means for efficiently explaining the technical spirit of the present invention to those skilled in the art to which the present invention pertains. It is only.

1 is a block diagram of a 3D emitter module according to the present invention.

As shown, the 3D emitter module 100 includes a receiver 110, a formatter 120, a transmitter 130, MCUs 140 and 150, and an IR modulator 160. It consists of a System on Chip (SoC) integrated into one chip.

The receiver 110 receives a 3D video signal input to the 3D emitter module 100 from the outside under the control of the MCU 140 and outputs the 3D video signal to the formatter 120.

The formatter 120 detects and analyzes the 3D video signal under the control of the MCU 140, and based on the result of the analysis under the control of the MCU 150, the first 3D synchronization synchronized with the 3D video signal. Generate a signal.

In addition, the formatter 120 outputs a 3D video signal to the transmitter 130 under control of the MCU 150, and outputs the generated first 3D sync signal to the IR modulator 160.

The IR modulator 160 performs an IR modulation (ie, modulates the 3D sync signal into an IR signal) to add a first 3D sync signal to a carrier frequency in a 30KHz to 60KHz band used in infrared communication, and thus the second 3D sync signal. Is sent to the outside.

The transmitter 130 transmits the 3D video signal output to the formatter 120 to the outside under the control of the MCU 150.

In the present invention, the receiver 110 receives the 3D video signal from the 3D player device, the transmitter 130 transmits the 3D video signal to the 3D display device, the IR modulator 160 is a third to the active stereoscopic glasses Outputs the 3D sync signal.

With the above configuration, the 3D emitter module 100 analyzes the received 3D video signal and generates and transmits a 3D sync signal synchronized with the 3D video signal.

2 is a block diagram of a 3D synchronization signal system according to the present invention.

As shown in the drawing, the 3D sync signal system includes a 3D player device 200, a 3D emitter module 100, a 3D display device 300, and an active stereoscopic glasses 400.

The 3D player device 200 is an external input device for inputting a 3D video signal to the 3D emitter module 100. Examples of the 3D player device 200 include a game console, a 3D Blu-ray player, a 3D DVD player, and a 3D vision PC.

The 3D emitter module 100 is composed of the components as shown in FIG. 1 and is connected to the 3D player device 200 with an HDMI cable to receive a 3D video signal through an HDMI port of the 3D player device 200.

The HDMI stands for High Definition Multimedia Interface, and the HDMI cable delivers HD-level high resolution digital video and audio signals without loss.

In addition, the 3D emitter module 100 is connected to the 3D display device 300 with an HDMI cable.

The 3D display apparatus 300 includes, for example, a 3D TV, a 3D projector, a 3D ready TV or a 3D monitor, and receives a 3D video signal to output a 3D image screen.

The 3D video signal input to the 3D emitter module 100 in the 3D player device 200 is detected and analyzed through the receiver 110, the MCU 140, and the formatter 120.

The formatter 120, the MCU 150, and the transmitter 130 generate a first 3D synchronization signal synchronized with the 3D video signal through the formatter 120, and output the 3D video signal to the 3D display apparatus 300 through an HDMI cable. .

In addition, the first 3D synchronization signal generated by the formatter 120 is transmitted to the active stereoscopic glasses 400 by the IR modulator 160, the second 3D synchronization signal modulated into an IR signal.

The active stereoscopic glasses 400 operate in accordance with the 3D synchronization signal so that the stereoscopic image output on the screen of the 3D display apparatus 300 can be viewed through the active stereoscopic glasses 400.

As such, the 3D emitter module 100 analyzes the 3D video signal input from the 3D player device 200 and generates a 3D sync signal synchronized with the 3D video signal through the 3D video signal to the 3D display device 300. The output 3D synchronization signal is transmitted to the active stereoscopic glasses 400 so that various 3D display apparatuses 300 may be connected to one 3D player apparatus 200 so that the 3D image may be viewed.

3 is a detailed block diagram of the stereoscopic glasses shown in FIG. 2.

As shown, the active stereoscopic glasses 400 include the input / output controller 410, the IR demodulator 420, the clock generator 430, the MCU 440, the driver 450, the left eye and the right eye shutter lenses 460a and 460b. ), A power management 470, a battery 480, a key 494 as an input / output means, and an LED 492.

The input / output controller 410 turns on the LED 492 when the stereoscopic glasses 400 are in operation under the control of the MCU 440, and transmits a signal input through the key 494 to the MCU 440.

The IR demodulator 420 receives and demodulates the second 3D sync signal transmitted from the IR modulator 160 of the 3D emitter module 100 to the MCU 440 to remove the IR signal. Output

When the first 3D synchronization signal is received, the MCU 440 may determine a driving cycle for opening and closing the left and right eye shutter lenses 260a and 260b based on the first 3D synchronization signal, and may determine the first 3D synchronization signal and the driving period. Accordingly, the driving unit 450 is controlled.

The driver 450 has a function of controlling the opening and closing operations of the left and right eye shutter lenses 460a and 460b. That is, the right eye shutter lens 260b is opened at the timing at which the right eye frame is output from the 3D emitter module 100, and the left eye shutter lens 260a is opened at the timing at which the left eye frame is output.

The clock generator 430 generates a timing signal (clock signal) necessary for synchronizing the driving of the left eye and right eye shutter lenses 260a and 260b and provides it to the MCU 440.

The battery 480 is built in the stereoscopic glasses 400 to supply the power required for operation to the stereoscopic glasses 400, the power management 470 is electrically connected to the battery 480 to charge the battery 480 or The power is supplied from the battery 480 to output or boost a constant voltage and supply the voltage to the clock generator 430, the IR demodulator 420, the driver 450, and the MCU 440.

The input / output controller 410, the IR demodulator 420, the clock generator 430, the MCU 440, the driver 450, and the power management 470 may be formed of a SoC 402 integrated into one chip. have.

In addition, by adopting a flexible LCD as the active stereoscopic glasses 400, it is possible to use a flexible plastic film instead of a rigid glass substrate to bend, bend, or roll so that there is no loss of display characteristics.

100: 3D emitter module 200: 3D player device
300: 3D display device 400: active stereoscopic glasses

Claims (7)

A receiver which receives an external 3D video signal and outputs the same to a formatter;
A formatter for detecting and analyzing the 3D video signal and generating a 3D synchronization signal synchronized with the 3D video signal based on the analysis result;
A first MCU controlling the receiver and the formatter to receive and detect a 3D video signal;
A transmitter for outputting the 3D video signal of the formatter to the outside;
An IR modulator for modulating the 3D synchronization signal into an IR signal and transmitting the IR signal to an external device through an infrared communication method; And
And a second MCU configured to control the formatter and the transmitter to transmit 3D video signals and generate 3D synchronization signals. The method of claim 1,
The receiver, the formatter, the first, the 2MCU, the transmitter, the IR modulator 3D emitter module, characterized in that made of a system on chip (SoC) integrated into one chip. The 3D emitter module of claim 1;
A 3D player device which is an external input device for inputting an external 3D video signal to the receiving unit;
A 3D display device for receiving a 3D video signal output from the transmitter and outputting a 3D image to a screen; And
3D synchronization signal system including an active stereoscopic glasses for opening and closing the left and right eye shutter lens in accordance with the 3D synchronization signal transmitted from the IR modulator. The method of claim 3,
The 3D emitter module is a 3D synchronization signal system, characterized in that connected to the 3D player device or 3D display device via an HDMI cable. The method of claim 3,
The active stereoscopic glasses are an input / output control unit that lights an LED when the active stereoscopic glasses are in operation and delivers a signal input through a key to the third MCU,
An IR demodulator for receiving and demodulating a 3D sync signal transmitted from an IR modulator of the 3D emitter module;
A third MCU to determine a driving period for opening and closing the left and right eye shutter lenses based on the demodulated 3D synchronization signal and to control the driving unit according to the synchronization signal and the driving period;
Driving unit for controlling the opening and closing operation of the left and right eye shutter lens,
And a clock generator for generating timing signals necessary for synchronizing the left eye and right eye shutter lens driving. The method of claim 5,
3D synchronization signal system, characterized in that the input / output controller, IR demodulator, MCU, driver, clock generator components are integrated into one chip. The method of claim 5,
The active stereoscopic glasses are 3D synchronization signal system, characterized in that to adopt a flexible LCD using a flexible plastic film.

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