KR101090179B1 - Display system for displaying 3-d images - Google Patents

Abstract

The present disclosure relates to a stereoscopic image display system in which a plurality of displays are disposed in close proximity to each other and each of the plurality of displays displays a basic image for forming a stereoscopic image. A first control signal having a first display to display and a signal selection unit to distinguish the first control signal linked to the first base image from the second control signal linked to the second base image displayed by the second display; A first stereoscopic image having a first signal transmitter for transmitting and a selective receiving unit for receiving the first control signal while avoiding interference of the second control signal and displaying a first basic image incident as a first stereoscopic image according to the first control signal It relates to a stereoscopic image display system comprising an image forming machine.

Description

Stereoscopic Image Display System {DISPLAY SYSTEM FOR DISPLAYING 3-D IMAGES}

The present disclosure generally relates to a stereoscopic image display system, and more particularly, to a stereoscopic image display system which improves stereoscopic image quality by preventing signal crosstalk.

This section provides background information related to the present disclosure which is not necessarily prior art.

In general, a stereoscopic image display system uses a binocular parallax to allow a user to recognize a stereoscopic sense at a near distance. Stereoscopic image display using binocular disparity includes a method of wearing glasses and a glasses-free method of not wearing glasses.

A typical method of wearing glasses is time division. In the time division method, the left eye image and the right eye image are displayed alternately at regular intervals, and a control signal having a synchronization signal of the left eye image and the right eye image is transmitted wirelessly. The glasses receive a control signal, and the left eye liquid crystal shutter and the right eye liquid crystal shutter of the glasses selectively block and transmit the incident image in synchronization with the period of the screen according to the control signal. Since the left eye image and the right eye image are alternately displayed through the glasses very quickly, the human vision hardly detects a time difference, so the human brain recognizes the left eye image and the right eye image as a stereoscopic image.

Stereoscopic images are used in various ways, such as medical, showing specific parts of the body, industrial for designing buildings or products, and three-dimensional games.In addition, a plurality of three-dimensional image display systems are placed in close proximity to certain spaces such as hospitals, offices, and recreation rooms. do.

When a plurality of displays are used together, the glasses frequently receive not only control signals linked to the glasses wearer's own display but also control signals linked to surrounding displays. As a result, the stereoscopic image formation is disturbed, and the image quality of the stereoscopic image is deteriorated. In particular, when a medical stereoscopic image used to examine or operate a patient in a hospital is distorted by crosstalk, there is a problem that the accuracy of examination or surgery is lowered and the risk of an accident is increased.

This will be described later in the Specification for Implementation of the Invention.

SUMMARY OF THE INVENTION Herein, a general summary of the present disclosure is provided, which should not be construed as limiting the scope of the present disclosure. of its features).

 A stereoscopic image display system in which a plurality of displays are disposed in close proximity to each other and each of the plurality of displays displays a base image for forming a stereoscopic image, comprising: a first display for displaying a first base image for forming a first stereoscopic image A first display and a signal selection unit for distinguishing the first control signal linked to the first base image from the second control signal linked to the second base image displayed by the second display and transmitting the first control signal; A first stereoscopic imager having a first signal transmitter and a selective reception unit for receiving a first control signal while avoiding interference by a second control signal, wherein the first basic image is displayed as a first stereoscopic image according to the first control signal. Provided is a stereoscopic image display system comprising a.

This will be described later in the Specification for Implementation of the Invention.

1 is a diagram illustrating an example of a stereoscopic image display system according to the present disclosure.
FIG. 2 is an example of a block diagram illustrating a stereoscopic image display system illustrated in FIG. 1.
3 is a diagram illustrating another example of a stereoscopic image display system according to the present disclosure.

The present disclosure will now be described in detail with reference to the accompanying drawing (s).

1 is a diagram illustrating an example of a stereoscopic image display system according to the present disclosure.

Referring to FIG. 1, the stereoscopic image display system 100 includes a display 110, a signal transmitter 130, and a stereoscopic image former 170. The stereoscopic image display system 100 provides a 3D image to a user. For example, the 3D image may include a medical image of a patient, an image of a building or a product, a character appearing in a game, and the like. The plurality of stereoscopic image display systems 100 and 200 may be disposed in close proximity to a limited space such as a hospital, an office, a game room, or the like. When it is necessary to distinguish the plurality of stereoscopic image display systems 100 and 200 from each other, terms such as 'first' and 'second' are used.

The display 110 receives display information from a control device such as the computer 105. The display information may include a synchronization signal such as RGB information of the pixel, a vertical synchronization signal, and a horizontal synchronization signal.

The display 110 displays the base image at a frequency of the synchronization signal, for example, 120 hertz (Hz) according to the display information. The base image is an optical signal emitted by the display 110, and the stereoscopic image former 170 to be described later selectively transmits the base image to form a stereoscopic image.

The base image may include a left eye image viewed from the left side of the object and a right eye image viewed from the right side. For example, the display 110 may alternately display a left eye image and a right eye image at 60 hertz, respectively.

FIG. 2 is an example of a block diagram illustrating a stereoscopic image display system illustrated in FIG. 1.

1 and 2, the signal transmitter 130 transmits a control signal 17 according to the stereoscopic image forming signal 13 transmitted from the computer 105. The control signal 17 includes information instructing the operation of the stereoscopic image former 170 in association with the synchronization signal of the base image.

A block diagram of the signal transmitter 130 and the stereoscopic image former 170 shown in FIGS. 1 and 2 is an example for explaining the operation of the display 110, the signal transmitter 130, and the stereoscopic image former 170. The circuit configuration of the elements constituting the signal transmitter 130 and the stereoscopic image former 170 may be modified in various ways.

The signal transmitter 130 may include a signal selection unit 131 and a signal transmission unit 135.

The signal selection unit 131 selects a transmission frequency of the control signal 17 according to the user's operation. For example, the signal selection unit 131 may include a signal generator 134, a transmission frequency selector 132, and a signal synthesizer 136.

The signal generator 134 generates a modulation signal 15 having a transmission frequency necessary for the transmission of the control signal 17. The transmission frequency selector 132 instructs the signal generator 134 to generate the modulated signal 15 having the transmission frequency 12 selected by the user. Alternatively, the transmission frequency selector 132 may select the modulation signal 15 having the required transmission frequency 12 among the plurality of modulation signals generated by the signal generator 134. The emission frequency may be selected in the infrared band, for example, the near infrared band.

The signal selection unit 131 includes a plurality of computers 105 and 205, displays 110 and 210, and signal transmitters 130 when a plurality of stereoscopic image display systems 100 and 200 are arranged in close proximity. 230 and / or stereoscopic imagers 170, 270. The signal selection unit 131 is operated by the user. For example, a dial for operating the transmission frequency selector 132 may be installed in the signal transmitter 130. Alternatively, the transmission frequency can be set by controlling the signal transmission unit 135 directly from the computer 105.

The signal synthesizing unit 136 combines the stereoscopic image forming signal 13 transmitted from the computer 105 and the modulation signal 15 having the transmission frequency 12 selected by the user and outputs the control signal 17.

The signal transmitting unit 135 emits the control signal 17 in the infrared. When the transmission frequency is selected in the infrared band, the signal transmission unit 135 may include an infrared light emitting diode. The control signal 17 linked to the synchronization signal of the base image is transmitted at the transmission frequency selected by the user.

The stereoscopic image former 170 receives the infrared rays transmitted from the signal transmitter 130 and forms a stereoscopic image according to the control signal 17. The stereoscopic image former 170 may have a shape of glasses worn by a user. Therefore, hereinafter, the stereoscopic image forming unit 170 is referred to as 'stereoscopic image glasses'.

2 illustrates an example of a block diagram of the stereoscopic image glasses 170. In FIG. 2, the stereoscopic image glasses 170 include a selective receiving unit 171, a liquid crystal shutter driving unit 173, a left eye liquid crystal shutter 175, and a right eye liquid crystal shutter 177.

The selective reception unit 171 may include a reception frequency selection unit 174 and a signal reception unit 172. The signal receiver 172 may include an infrared receiver sensor.

The reception frequency selector 174 sets the transmission frequency of the control signal 17 as the reception frequency, and blocks signals having a frequency different from the reception frequency from the signal received by the signal receiver 172. The reception frequency selection unit 174 may automatically set the reception frequency to the transmission frequency determined by the transmission frequency selection unit 132. Alternatively, the reception frequency selector 174 may be controlled directly by the user or on the computer 105 like the transmission frequency selector 132. The control signal 17 detected by the selective reception unit 171 is applied to the liquid crystal shutter driving unit 173.

The liquid crystal shutter driving unit 173 controls the operations of the left eye liquid crystal shutter 175 and the right eye liquid crystal shutter 177 according to the control signal 17. The liquid crystal shutter driving unit 173 opens the left eye liquid crystal shutter 175 and closes the right eye liquid crystal shutter 177 for the time when the left eye image 21 is displayed in the base image. In addition, the liquid crystal shutter driving unit 173 opens the right eye liquid crystal shutter 177 and closes the left eye liquid crystal shutter 175 for the time when the right eye image 23 is displayed in the base image. As the left eye image 21 and the right eye image 23 are alternately displayed at 60 Hz each as described above, the user recognizes a stereoscopic image in which the left eye image and the right eye image are integrated.

As described above, a plurality of stereoscopic image display systems 100 and 200 may be disposed in close proximity and used in a limited space such as a hospital, an office, or an entertainment room. For example, in the vicinity of the first display 110, the first signal transmitter 130 and the first stereoscopic image glasses 170, the second display 210, the second signal transmitter 230 and the second stereoscopic image glasses 270 may be disposed.

Unlike the stereoscopic image display system 100 described with reference to FIGS. 1 and 2, when the first signal transmitter 130 and the second signal transmitter 230 use the same emission frequency, the first stereoscopic image glasses 170 ) May receive the first control signal 17 from the first signal transmitter 130 and the second control signal 27 from the second signal transmitter 230. As a result, the first stereoscopic image may not be formed or the image quality of the first stereoscopic image may be degraded.

Alternatively, according to the stereoscopic image display system 100 according to the present disclosure, the transmission frequency selector 132 of the first signal transmitter 130 and the second signal transmitter 230 is adjusted to control the first control signal 17. And the second control signal 27 are transmitted at different transmission frequencies. In addition, the reception frequency selector 174 of the first stereoscopic image glasses 170 and the second stereoscopic image glasses 270 is adjusted so that the first stereoscopic image glasses 170 receives only the first control signal 17. The second stereoscopic image glasses 270 receive only the second control signal 27.

Therefore, the formation of the first stereoscopic image and the second stereoscopic image due to the crosstalk of the first control signal 17 and the second control signal 27 or the deterioration of the image quality of the first stereoscopic image and the second stereoscopic image are prevented. .

A user may give a plurality of stereoscopic image display systems a unique frequency that is distinguished from each other, and the transmission frequency selection unit 132 of the signal transmitter 130 and the reception frequency selection unit 174 of the stereoscopic image glasses 170 may be provided. Each can be set to its own transmit and receive frequency.

3 is a diagram illustrating another example of a stereoscopic image display system according to the present disclosure.

The stereoscopic image display system 400 illustrated in FIG. 3 is substantially the same as the stereoscopic image display system 100 described with reference to FIGS. 1 and 2 except for the signal transmitter 430. Therefore, redundant description is omitted.

Referring to FIG. 3, the signal transmitter 430 emits a plurality of control signals 77 and 87 in cooperation with the plurality of displays 410 and 510. For example, the signal transmitter 430 is interlocked with the first control signal 77 interlocked with the first base image displayed by the first display 410 and the second base image displayed by the second display 410. All of the second control signals 87 are emitted.

The signal transmitter 430 may include a signal selection unit and a signal transmission unit.

The signal selection unit includes a transmission frequency selector. The user may control the transmission frequency selector to select different transmission frequencies of the first control signal 77 and the second control signal 87. The signal transmitting unit may simultaneously radiate or alternately radiate the first control signal 77 and the second control signal 87.

The user controls the reception frequency selection unit of the first stereoscopic image glasses 470 to set the transmission frequency of the first control signal 77 as the reception frequency, and controls the reception frequency selection unit of the second stereoscopic image glasses 570 to control the reception frequency selection unit. 2 The transmission frequency of the control signal 87 can be set as the reception frequency.

Therefore, the first stereoscopic image glasses 470 receive only the first control signal 77 to avoid the interference of the second control signal 87, and the second stereoscopic image glasses 570 interfere with the first control signal 77. Avoids and receives only the second control signal 87. Therefore, the obstacle of stereoscopic image formation due to the crosstalk between the first control signal 77 and the second control signal 87 is prevented.

In the stereoscopic image display system 400 illustrated in FIG. 3, one signal transmitter 430 transmits a plurality of control signals 77 and 87, thereby reducing the number of devices configuring the system.

Hereinafter, various embodiments of the present disclosure will be described.

1, 2, and 3 illustrate a system for preventing crosstalk between control signals by varying control signal transmission frequencies of the plurality of stereoscopic image display systems 100, 200, and 400. Alternatively, it is possible to distinguish the control signals from each other by adding a unique identification signal to the control signal while maintaining the same control signal transmission frequency of the plurality of stereoscopic image display systems.

For example, the signal transmitter may include a signal selection unit and a signal transmission unit. The signal selection unit may include a signal generator, an identification signal generator, and a signal synthesizer. The signal generator generates a modulated signal having a transmission frequency for transmitting the control signal.

The identification signal generator may be controlled by the user. The identification signal generator of the first signal transmitter generates an identification signal that distinguishes the first signal transmitter from other signal transmitters. The signal synthesizer generates a control signal by synthesizing the identification signal, the stereoscopic image forming signal, and the modulation signal. The signal transmitting unit emits a control signal.

The selective reception unit of the stereoscopic image glasses may include a filtering unit that detects an identification signal added to the control signal. Accordingly, the first stereoscopic image glasses select only the first control signal to form the first stereoscopic image, and the second stereoscopic image glasses select only the second control signal to form the second stereoscopic image.

When the transmission frequencies of the plurality of control signals are the same and the identification signal is added to the control signals, the signal transmitter and the stereoscopic image glasses can be made simpler than when the transmission frequencies are different from each other.

(2) Unlike the signal transmitter of the infrared communication method described in FIGS. 1, 2 and 3, the signal transmitter of the stereoscopic image display systems 100 and 400 may be configured by a radio frequency (RF) communication method. .

In this case, the signal transmitter includes a signal selecting unit and a signal transmitting unit. The user can control the signal selection unit to select the transmission frequency to have a frequency suitable for the RF communication method, for example, a frequency lower than the near infrared.

The signal transmitting unit may be an RF communication unit for transmitting the control signal, and the RF communication unit may include, for example, a transmitting antenna. Also, the selective reception unit of the stereoscopic image glasses may include a reception antenna and a reception frequency selection unit.

When the signal transmitter and the stereoscopic image glasses are interlocked by the RF communication method, the stereoscopic image glasses may receive the control signal even if there is another object between the signal transmitter and the stereoscopic image glasses.

According to the stereoscopic image display system described in FIGS. 1, 2 and 3 according to the present disclosure, the stereoscopic image is well formed and image quality is improved by preventing crosstalk between control signals.

In addition, according to another stereoscopic image display system according to the present disclosure, by preventing crosstalk between the control signals, the stereoscopic image is well formed and the image quality is improved, and even if there is an obstacle, the control signal can be received, thereby improving the performance of the stereoscopic image display system. do.

100: stereoscopic image display system 110: display
130: signal transmitter 170: stereoscopic image glasses

Claims (10)

In a stereoscopic image display system in which a plurality of displays are disposed adjacent to each other and each of the plurality of displays displays a basic image for forming a stereoscopic image,
A first display displaying a first base image for forming a first stereoscopic image;
A second display displaying a second base image for forming a second stereoscopic image;
A signal transmitter for transmitting a first control signal linked to the first base image and a second control signal linked to the second base image; a signal having a signal selection unit for distinguishing the first control signal from the second control signal Discharge machine;
A first stereoscopic image former having a first selective receiving unit for receiving a first control signal avoiding interference by a second control signal, and displaying the incident first basic image as a first stereoscopic image according to the first control signal; And
A second stereoscopic image former having a second selective receiving unit for receiving a second control signal to avoid interference by the first control signal, and displaying the incident second basic image as a second stereoscopic image according to the second control signal; Stereoscopic image display system comprising a. The method according to claim 1,
The first basic image includes a first left eye image and a first right eye image which are alternately displayed.
The first stereoscopic imager includes a first left eye liquid crystal shutter that transmits only the first left eye image and a first right eye liquid crystal shutter that transmits only the first right eye image according to the received first control signal.
The second basic image includes a second left eye image and a second right eye image which are alternately displayed.
The second stereoscopic imager includes a second left eye liquid crystal shutter that transmits only the second left eye image according to the received second control signal, and a second right eye liquid crystal shutter that transmits only the second right eye image. system. The method according to claim 1,
Signal transmitter
A first signal transmitter having a first signal selection unit and transmitting a first control signal; And
And a second signal transmitter provided separately from the first signal transmitter, having a second signal selection unit, and transmitting a second control signal. The method according to claim 3,
The first signal selection unit includes a first transmission frequency selection unit for adjusting the transmission frequency of the first control signal,
And the second signal selection unit includes a second transmission frequency selector for adjusting the transmission frequency of the second control signal. The method according to claim 3,
The first selective receiving unit includes a first receiving frequency selector which receives a first control signal by adjusting a receiving frequency at a sending frequency of the first control signal,
And the second selective receiving unit comprises a second receiving frequency selector which receives a second control signal by adjusting a receiving frequency at a sending frequency of the second control signal. The method according to claim 3,
The first signal selection unit includes a first identification signal generator that adds an identification signal that distinguishes the first signal transmitter from the second signal transmitter to the first control signal,
And the second signal selection unit includes a second identification signal generator for adding an identification signal for distinguishing the second signal transmitter from the first signal transmitter to the second control signal. The method of claim 6,
And the first selective receiving unit and the second selective receiving unit each include a filtering unit for selecting the first control signal and the second control signal to which the identification signal is added from the received signals. The method according to claim 3,
The first control signal includes a synchronization signal for the first base image, the second control signal includes a synchronization signal for the second base image, and the first signal transmitter and the second signal transmitter respectively control the first with infrared light. And an infrared ray transmitting unit configured to transmit a signal and a second control signal. The method according to claim 3,
The first control signal includes a synchronization signal for the first base image, the second control signal includes a synchronization signal for the second base image, and the first signal transmitter and the second signal transmitter are each radio frequency (RF). And an RF communication unit for transmitting the first control signal and the second control signal in a communication method. The method according to claim 9,
Each of the first display and the second display includes a medical image generator,
The first display alternately displays the first left eye image and the first right eye image of the first medical image according to a synchronization signal as a first basic image generated by the medical image generator.
The second display is a second basic image generated by the medical image generator, wherein the second left eye image and the second right eye image of the second medical image are alternately displayed according to a synchronization signal.

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