KR101315857B1 - Extraction system for screen gap based on display wall, and extraction method thereof - Google Patents

Abstract

PURPOSE: A screen gap extraction system and a method thereof are provided to remove visual areas in screen gaps due to boundaries of multiple screens and effectively control illumination and projecting angles of an optical engine. CONSTITUTION: A projection display device (110) forming a screen wall (100) comprises a main housing forming an external appearance; a screen (113) mounted at an opening of the front of the main housing; an optical engine (114) installed inside of the main housing; a reflector (112) inclinedly installed inside of the main housing to reflect incident light emitted from the optical engine in the direction of the screen on which an image is formed.

Description

Extraction system for screen gap based on display wall, and extraction method

The present invention relates to a display wall-based screen gap extraction system and a screen gap extraction method according to an embodiment of the present invention, and more particularly, screen gaps (A, B) implemented by a case outline of a plurality of screens. Display wall-based screen gap expansion to enable energy saving by not only playing the video screen with the removed state of the visualization area but also effectively adjusting the optimized illuminance and angle of the optical engine formed on the back of each screen. Traction system and screen gap extraction method.

In the display wall (patent application No. 10-2010-0098614) having deformation prevention and spacing functions according to the prior art, a plurality of screens for the display wall are stacked in a vertical, horizontal direction, and the sides of adjacent screens are in contact with each other. Since the thermal deformation occurs on each screen, the displacement width in the left and right directions (in particular, the displacement amount (a) at both ends is large enough to distort the image) is not only large, but also causes distortion in the image. When the screen is cooled again, the gap between the screen and the screen is generated, which causes the disconnection of the image. Therefore, the problem of causing a serious problem in that the entire image to be expressed cannot be implemented stably is solved.

However, in addition to these problems, since the display wall is formed of a plurality of screens, screen gaps are formed between the screens, so that the user may have difficulty in reading characters or identifying images by the visualization area of the screen gaps.

[Related Technical Literature]

1. Method for displaying information for viewing by user and multi-focal plan display (method for displaying information for viewing by user and multi-focal plan display) (Patent Application No. 10-2003-7014295)

2. Display wall with deformation prevention and spacing function (Patent Application No. 10-2010-0098614)

The present invention is to solve the above problems, not only to reproduce the video screen in the removed state of the visualization area of the screen gap (A, B) implemented by the outer shell of the plurality of screens, but also effectively the back of each screen The present invention provides a display wall-based screen gap extraction system and a screen gap extraction method for adjusting energy intensity and angle of the optical engine formed in the apparatus.

However, the objects of the present invention are not limited to the above-mentioned objects, and other objects not mentioned can be clearly understood by those skilled in the art from the following description.

In order to achieve the above object, a display wall-based screen gap extraction method according to an embodiment of the present invention includes a screen group 110 in which the screen gap extraction module 124 constitutes the display wall 100. Row) by the number of screen gaps (A, B) of each of the screens 113 with respect to the optical engine 114 formed on the back of each of the screens 113 of M (columns), vertical irradiation angle and horizontal irradiation A first step of reproducing the image screen implemented in the removed state of the visualization regions of the screen gaps A and B through motion control of the angles; .

In this case, after the first step, the screen gap extraction module 124 is not removed by the first step by adjusting the angle with respect to the reflecting plate 112 formed on the back of each of the screen 113 ( A second step of performing removal on the visualization area of A, B); Is further preferably performed.

In addition, in the first step, the screen gap extraction module 124 is N (rows) by M, which is the screen group 110 constituting the display wall 100 to display the implemented image data from the image source storage unit 123. A first step of analyzing the position of each screen 113 through a process of recognizing identification information of each of the screens 113 in the column, and storing the analyzed "location information" in the storage unit 127; And a vertical screen gap A and a horizontal screen gap B formed by the screen gap extraction module 124 formed by the screen edges 115 of the screens 113 of N (rows) by M (columns). A first step 1-2 of analyzing the position of the data and storing the analyzed "position shape information" in the storage unit 127; .

In addition, in the first step, after the first and second steps, the screen gap extraction module 124 may be configured for each of the screens 113 of N (row) by M (column) based on the position shape information. The screen for each screen 113 is classified by performing a classification of whether the number of screen gaps A and B corresponding to the sum of the vertical screen gap A and the horizontal screen gap B is 2, 3, or 4 A first to third step of storing gap classification information " on the storage unit 127; .

In addition, in the first step, after the first to third steps, the screen gap extraction module 124 separately divides the screen 113 having the number of the screen gaps A and B into four, 113, and the screen A first to fourth step of extracting positions of the screens 113 having two and three gaps A and B from the position information stored in the storage unit 127 in step 1-1; Is further preferably performed.

In addition, in the first step, after the steps 1-4, the screen gap extraction module 124 is provided on each screen 113 for the screen 113 having four screen gaps A and B. A first to fifth step of controlling illuminance of the outer area irradiated from the light of the optical engine 114 formed on the rear side to project the implemented image data by a predetermined amount; Is further preferably performed.

In addition, in the first to fifth stages, each light of the optical engine 114 is formed of an aggregate of a plurality of light emitting elements, or a dimming function for controlling the illumination of a peripheral area that is distinguished from a center constituting the light. It is preferable to have a.

In addition, in the first step, the optical engine 114 may be applied to each of the screens 113 in which the screen gap extraction module 124 has two screen gaps A and B after the steps 1-5. For the vertical angle for the adjustment of the irradiation angle of the vertical angle is proportional to the number of N, the horizontal angle is adjusted to the screen gap on the basis of the "position shape information" analyzed in the above steps 1-3 A first to sixth step of controlling the number of points A and B to face a center point of a square shape formed by the screen 113 having four numbers; Is further preferably performed.

In addition, in step 1-6, the screen gap extraction module 124 has a vertical irradiation angle and a horizontal irradiation angle with respect to each of the screens 113 having two and three screen gaps A and B. In the control of the reflected light (PL) that forms the screen gap (A, B) visualization area of the plurality of reflected light (PL) irradiated from each of the optical engine 114 for projecting the real image data through the reflecting plate 112 ) Is preferably controlled to face the center point of the quadrangular shape formed by the screen 113 having four screen gaps (A, B).

In addition, in the second step, the screen gap extraction module 124 receives the captured image data of the image screen implemented in the display wall 100 by an external camera 200 through short-range wireless communication. After analyzing the screen gap (A, B) image state through image recognition, there is an area that is not removed from the screen gap (A, B) image of the entire screen 113 constituting the display wall 100 Step 2-1 of extracting the screen 113; .

In addition, in the second step, after the step 2-1, the screen gap extraction module 124 is formed on the back surface of each of the at least one or more screens 113 extracted by the step 2-1 ( A second step 2-2 such that the angle adjustment is performed vertically or horizontally with respect to 114); Is further preferably performed.

In addition, in the second step 2-2, the screen gap extraction module 124 does not remove the illuminance of each of the optical engines 114 from the light of the extracted screen gap A and B images. It is desirable to control so that angle control is performed for each of the reflecting plates 114 formed on the increasing rear surface.

In order to achieve the above object, a display wall-based screen gap extraction system according to an embodiment of the present invention includes a screen of N (row) by M (column), which is the screen group 110 constituting the display wall 100. (113); An optical engine 114 formed on a rear surface of each of the screens 113; And screen gaps A and B through operation control of illuminance, vertical irradiation angle, and horizontal irradiation angle according to the number of screen gaps A and B of each of the screens 113 with respect to each of the optical engines 114. Optical engine projection light adjusting means (124c) for reproducing the image screen implemented in the removed state for the visualization area of the display; .

At this time, the system according to the present invention, for the visualization area of the screen gap (A, B) not removed by the first step by adjusting the angle to the reflector plate 112 formed on the back of each of the screen 113 Reflector angle control means 124f for performing removal; .

The display wall-based screen gap extraction system and the screen gap extraction method according to an embodiment of the present invention are removed with respect to the visualization area of the screen gaps A and B implemented by the case outline of the plurality of screens. In addition to reproducing the image screen, by effectively adjusting the optimized illuminance and angle of the optical engine formed on the back of each screen, it provides an energy-saving effect.

1 is a diagram illustrating a display wall 100 in a display wall based screen gap extraction system according to an exemplary embodiment of the present invention.
FIG. 2 is a diagram for describing a structure of a screen 111 formed of N (rows) by M (columns) in the display wall 100 of FIG. 1.
3 is a view for explaining the structure of the screen edge 115 in the display wall 100 of FIG.
4 is a diagram illustrating a display wall-based screen gap extraction system according to an embodiment of the present invention.
5 is a view for explaining the configuration of the screen gap control terminal 120 formed in the display wall 100 of the screen gap extraction system based on the display wall of FIG.
6 is a view for explaining the effect of removing the screen gap (A, B) in the display wall-based screen gap extraction system according to an embodiment of the present invention.
7 is a diagram illustrating a display wall-based screen gap extraction method according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a detailed description of preferred embodiments of the present invention will be given with reference to the accompanying drawings. In the following description of the present invention, detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

In the present specification, when any one element 'transmits' data or signals to another element, the element can transmit the data or signal directly to the other element, and through at least one other element Data or signal can be transmitted to another component. Meanwhile, in the present invention, screen gaps A and B are used as abbreviations for vertical screen gaps A and horizontal screen gaps B.

1 is a diagram illustrating a display wall 100 in a display wall based screen gap extraction system according to an exemplary embodiment of the present invention. FIG. 2 is a diagram for describing a structure of a screen 111 formed of N (rows) by M (columns) in the display wall 100 of FIG. 1. 3 is a view for explaining the structure of the screen edge 115 in the display wall 100 of FIG. 4 is a diagram illustrating a display wall-based screen gap extraction system according to an embodiment of the present invention. 5 is a view for explaining the configuration of the screen gap control terminal 120 formed in the display wall 100 of the screen gap extraction system based on the display wall of FIG. FIG. 6 is a diagram for describing an effect of removing a screen gap A and B from a visualization area of a display wall based screen gap extraction system according to an exemplary embodiment of the present invention.

1 to 6, the display wall-based screen gap extraction system includes a display wall 100 and an external camera 200 for fine adjustment of the screen gaps A and B. The display wall 100 includes a projection display device 110 and a screen gap control terminal 120. The projection display apparatus 110 is divided into a main housing 111, a reflecting plate 112, a screen 113, an optical engine 114, and a screen edge 115.

And, as shown in Figure 1, it is most preferably formed of a screen gap extraction system based on the display wall 100 formed of the projection display device 110 including only the screen 113 of 3 (row) by 3 (column) As described later in the present invention, since the display wall 100 can be used in a scalable form, the screen 113 having an array of N (rows) by M (columns) as shown in FIG. Explain that it assumes). In this case, one row by one column screen {113 (1,1)} corresponding to four vertices of the quadrangle of the projection display apparatus 110, and one row by M column (M is a natural number of two or more) {113 (1, M)}, N rows (N is a natural number of two or more) by one column of screens {113 (n, 1)}, and N rows by M columns of screens {113 (n, m)}. The basic unit in which one screen gap extraction method is performed is a screen {113 (x, y)}, a screen {113 (x, y + 1)}, and a screen {113 (x + 1, y) as shown in FIG. ), And the screen {113 (x + 1, y + 1)} can be described based on four cells. In this case, although not displayed between the screen {113 (x, y)} and the screen {113 (x, y + 1)}, a visualization area of the vertical screen gap A is formed, and the screen {113 (x, y) ) And the screen {113 (x + 1, y)}, as indicated, a visualization area of the horizontal screen gap B is formed. As such, the reason why the vertical screen gap A and the horizontal screen gap B are visualized is because a screen edge 115 layer adjacent to each other among the main housings 111 is formed on each screen 113.

Since the screen edge 115 is generally provided to the user as an implementation image as shown in FIG. 6A, the present invention is pointed out as a problem. In the present invention, the image of the screen edge 115 is removed as shown in FIG. 6B. The purpose of the present invention is to provide an energy-saving display wall 100 by adjusting the illuminance effectively while being provided.

On the other hand, the projection display device 110 constituting the display wall 100 is the main housing 111 forming the appearance, the screen 113 mounted on the opening in the front of the main housing 111, the main housing 111 An optical engine 114 mounted therein and a reflector plate 114 mounted obliquely inside the main housing 111 to reflect projection light emitted from the optical engine 114 toward the screen 113 where an image is formed. Doing.

The screen gap control terminal 120 includes an optical engine control module 121, an image source and reflection control unit 122, an image source storage unit 123, a screen gap extraction module 124, and a reflection plate angle control module 125. ), A WPAN transceiver 126, and a storage unit 127. In addition, the screen gap extraction module 124 may include an optical engine positioning unit 124a, a screen gap positioning unit 124b, an optical engine projection light adjusting unit 124c, an image recognition unit 124d, and a feedback control unit ( 124e) and reflector angle control means 124f. The short range wireless communication method used in the WPAN transceiver 126 may be implemented using Bluetooth, Zigbee, or the like.

Hereinafter, the screen gap extraction system based on the display wall will be described in detail with reference to the configuration of the screen gap extraction module 124.

The optical engine positioning unit 124a is configured to irradiate the implemented image data from the image source storage unit 123 to the screen 113 of N (row) by M (column) constituting the display wall 100. The position of each screen 113 is analyzed through identification information recognition process for each screen 113 formed inside the 113, and the optical engine 114 of each screen 113 is vertical in a default state and The optical engine control module 121 is controlled to set at a horizontal angle.

Thereafter, the optical engine positioning unit 124a stores the " positional information " of each screen 113 in the storage unit 127. Here, each screen 113 is formed of a modular modular, and the location information storage by the optical engine positioning means 124a is meaningful to enable the use as the expandable display wall (100).

The screen gap positioning means 124b is a vertical screen formed by each of the screens 113 of N (rows) by M (columns) in which position information analysis of each screen 113 is completed by the optical engine positioning means 124a. The position of the gap A and the horizontal screen gap B are analyzed using the position information by the optical engine position detecting means 124a, not the analysis of the image, thereby generating " position shape information " The data is stored in the storage unit 127 (S12). Here, the position formation information means screen gaps (A, B) information for each screen 113.

The screen gap position setting means 124b corresponds to the sum of the vertical screen gap A and the horizontal screen gap B in the screen 113 of N (row) by M (column) as the analyzed position shape information. The screen gap classification information for each screen 113 is stored on the storage unit 127 by classifying whether the number of screen gaps A and B is 2, 3, or 4.

The optical engine projection light adjusting means 124c separates and separates the screen 113 having four screen gaps A and B analyzed by the screen gap position setting means 124b. The position of the screen 113 having two and three screen gaps A and B is extracted from the position information stored in the storage unit 127 by the optical engine positioning means 124a.

The optical engine projection light adjusting means 124c irradiates from the light of the optical engine 114 for projecting implemented image data on each screen 113 for the screen 113 having the number of screen gaps A and B. The optical engine control module 121 is controlled to improve the illuminance of the outer area to be preset. To this end, each light of the optical engine 114 is preferably formed of an assembly of a plurality of light emitting elements, or at least has a dimming function (dimming function) for controlling the illuminance to the peripheral area that is distinguished from the center constituting the light. Do.

The optical engine projection light adjusting means 124c is formed by a plurality of screens 113 when the vertical irradiation angle of the optical engine 114 is adjusted with respect to the screen 113 having two or three screen gaps A and B. Angle adjustment proportional to the number of rows N in the array, and the number of rows in the array formed by the plurality of screens 113 when the horizontal irradiation angle of the optical engine 114 is adjusted. The optical engine control module 121 is controlled to perform angle adjustment in proportion to the number of phosphorus Ms.

In this case, the optical engine projection light adjusting means 124c implements the image data through the reflector plate 112 when the optical engine control module 121 controls the vertical irradiation angle and the horizontal irradiation angle of each optical engine 114. Screens of which the number of screen gaps A and B is 4 is the reflected light PL that forms the screen gaps A and B visualization areas among the plurality of reflected light PLs irradiated from the optical engine 114 for projecting the And toward the center point of the rectangular shape determined as "position shape information" analyzed by the screen gap position setting means 124b.

Here, the reflected light PL may be regarded as one of PL-a or PL-b according to the position of the screen 113 when the vertical irradiation angle is adjusted as shown in FIG. 3.

That is, in the screen 113 composed of an array of N (rows) by M (columns), the screen 113 having the number of screen gaps A and B is formed on the rectangular edge of the projection display apparatus 110. It is formed in a rectangular shape as a whole inside the corresponding screen 113, the reflected light irradiated by the optical engine 114 inside each screen 113 and reflected by the reflecting plate 112 to face the center point of the rectangular shape ( PL) is controlled by the optical engine projection light adjusting means 124c.

When the image recognition means 124d controls the illuminance and the reflected light PL by the optical engine 114 inside each screen 113 by the optical engine projection light adjusting means 124c, the image recognition means 124d is connected to the external camera 200. The WPAN transceiver 126 is controlled to receive the captured image data of the image screen implemented in the display wall 100 through short-range wireless communication.

The image recognizing means 124d analyzes the screen gap (A, B) image states formed by the plurality of screens 113 through image recognition on the captured image data, and then configures the screen constituting the display wall 100 ( 113) The screen 113 in which the unremoved region exists among the screen gaps A and B images is extracted.

When the feedback control means 124e completes the analysis of the screen gap (A, B) image state according to the image recognition by the image recognition means 124d, the screen on each of the screens 113 constituting the display wall 100 is completed. An area not removed from the gap A and B images is extracted.

The reflector angle control means 124f controls the reflector angle control module 125 vertically or horizontally with respect to the reflector plate 114 formed on the rear surface of each of the at least one screen 113 extracted by the image recognition means 124d. do. In this case, the reflector angle control means 124f increases the illuminance of the light of the optical engine 114 to an area which is not removed among the screen gaps A and B images extracted by the feedback control means 124e. Control the reflector angle control module 125 to perform a fine angle control for).

7 is a diagram illustrating a display wall-based screen gap extraction method according to an embodiment of the present invention. 1 to 7, steps S11 to S16 represent a main operation mechanism as an operation area of the optical engine 114 control operation flow, and steps S17 and S18 refer to a reflector plate (S18). 112. Control operation flow region, which shows the complementary operation mechanism. First, the screen gap extraction module 124 examines the implemented image data from the image source storage unit 123 to the screen 113 of N (row) by M (column) constituting the display wall 100. After analyzing the position through the identification information recognition process for each screen 113, and stores the analyzed "location information" in the storage unit 127 (S11).

After the step S11, the screen gap extraction module 124 is configured with a vertical screen gap A and a horizontal screen gap B formed by each of the screens 113 of N (rows) by M (columns) where the positional analysis is completed. ) Stores the analyzed "position shape information" in the storage unit 127 (S12).

After step S12, the screen gap extraction module 124 performs a vertical screen gap A on the screen 113 of N (row) by M (column) based on the position shape information analyzed in step S12. A storage unit stores "screen gap classification information" for each screen 113 by classifying whether the number of screen gaps A and B corresponding to the total number of horizontal screen gaps B is 2, 3, or 4. In operation S13, the process is stored on (127).

After step S13, the screen gap extraction module 124 separately separates the screen 113 having the number of screen gaps A and B analyzed in step S13 from four, and screen gaps A and B. The position of the screen 113 having the number of two and three is extracted from the position information stored in the storage unit 127 in step S11 (S14).

After step S14, the screen gap extraction module 124 is configured to project the image data on the screen 113 for the screen 113 having the number of screen gaps A and B on the screen 113. Control to improve the illuminance of the outer area irradiated from the light of the predetermined amount by a predetermined amount (S15). To this end, each light of the optical engine 114 is preferably formed of an assembly of a plurality of light emitting elements, or has a dimming function for controlling the illuminance of the peripheral area peripheral area distinguished from the center constituting the light.

After the step S15, the screen gap extraction module 124 performs vertical angles for adjusting the irradiation angle of the optical engine 114 with respect to each of the screens 113 having two or three screen gaps A and B. For the angle adjustment proportional to the number of N for the horizontal angle, and the angle adjustment proportional to the number of M for the horizontal angle, the number of screen gaps (A, B) based on the "position shape information" analyzed in step S12 is Control to face the center point of the rectangular shape formed by the four screen 113 (S16).

 More specifically, the screen gap extraction module 124 is formed of a plurality of screens 113 when the vertical irradiation angle of the optical engine 114 is adjusted with respect to the screen 113 having two screen gaps A and B. It is proportional to the number of rows N in the array, and M, the number of rows in the array formed by the plurality of screens 113 when the horizontal irradiation angle of the optical engine 114 is adjusted. Performs angle adjustment in proportion to the number, and a plurality of irradiated from the optical engine 114 for projecting the real image data through the reflector 112 in the control of the vertical irradiation angle and the horizontal irradiation angle of each optical engine 114 The reflected light PL, which forms the screen gaps A and B, of the reflected light PLs, is directed toward the center point of the quadrangular shape formed by the screen 113 having four screen gaps A and B. do.

Here, the reflected light PL may be regarded as one of PL-a or PL-b according to the position of the screen 113 when the vertical irradiation angle is adjusted as shown in FIG. 3.

After step S16, the screen gap extraction module 124 receives the captured image data on the image screen implemented in the display wall 100 by the external camera 200 through short-range wireless communication, thereby performing image recognition. After analyzing the screen gap (A, B) image state through the screen 113, the area of the screen gap (A, B) that is not removed from the entire screen 113 constituting the display wall (100) It is extracted (S17).

After the step S17, the screen gap extraction module 124 may adjust the fine angle vertically or horizontally with respect to the reflector plate 114 formed on the rear surface of each of the one or more screens 113 extracted by the step S17. In this case, fine angle control is performed on the reflector plate 114 which increases the illuminance of the light of the optical engine 114 to the unremoved area of the screen gaps A and B images extracted in step S17. (S18).

As described above, preferred embodiments of the present invention have been disclosed in the present specification and drawings, and although specific terms have been used, they have been used only in a general sense to easily describe the technical contents of the present invention and to facilitate understanding of the invention , And are not intended to limit the scope of the present invention. It is to be understood by those skilled in the art that other modifications based on the technical idea of the present invention are possible in addition to the embodiments disclosed herein.

100: display wall
110: projection display device
111: main housing
112: reflector
113: screen
114: optical engine
115: screen border
120: screen gap control terminal
121: optical engine control module
122: image source and reflection control unit
123: image source storage unit
124: screen gap extraction module
124a: optical engine positioning means
124b: screen gap position setting means
124c: optical engine projection light adjusting means
124d: image recognition means
124e: feedback control means
124f: reflector angle control means
125: reflector angle control module
126: WPAN transceiver
127: storage

Claims (14)

The screen gap extraction module 124 is applied to the optical engine 114 formed on the back surface of each of the screens 113 of N (rows) by M (columns), which are the screen groups 110 constituting the display wall 100. Through the control of the illuminance, the vertical irradiation angle, and the horizontal irradiation angle according to the number of screen gaps A and B of each of the screens 113, the screen gaps A and B are implemented in the removed state of the visualization area. A first step of playing a video screen; Display gap based screen gap extraction method comprising a.
The method according to claim 1, After the first step,
The screen gap extraction module 124 is located in the visualization area of the screen gaps A and B which are not removed by the first step by adjusting the angle of the reflecting plate 112 formed on the rear surface of each of the screens 113. Performing a removal for the second step; Display gap based screen gap extraction method comprising a.
The method of claim 2, wherein the first step,
The screen gap extraction module 124 displays N (rows) by M (columns), which is a screen group 110 constituting the display wall 100, from the image source storage unit 123. A first step of analyzing the position of each screen 113 through the identification information recognition process for each, and storing the analyzed "position information" in the storage unit 127; And
The screen gap extraction module 124 of the vertical screen gap (A) and the horizontal screen gap (B) formed by the screen edges 115 of each of the screen 113 of the N (row) by M (column) A first and second step of analyzing the position and storing the analyzed "position shape information" in the storage unit 127; Display gap based screen gap extraction method comprising a.
4. The method of claim 3,
After the first and second steps, the screen gap extraction module 124 is vertical to the screen gap A and horizontal to each of the screen 113 of N (row) by M (column) based on the position shape information. The storage unit is configured to classify whether the number of screen gaps A and B corresponding to the sum total of the screen gaps B is 2, 3, or 4, so as to display “screen gap classification information” for each screen 113. Step 1-3 of storing on 127; Screen gap extraction method based on the display wall further comprises.
The method of claim 4, wherein the first step,
After the first to third steps, the screen gap extraction module 124 separately classifies the screen 113 having four screen gaps A and B, and the number of screen gaps A and B. A first to fourth step of extracting positions of the screen 113 having two and three points from the position information stored in the storage unit 127 in step 1-1; Screen gap extraction method based on the display wall further comprises.
6. The method of claim 5,
After the above steps 1-4, the screen gap extraction module 124 is reared to project the implemented image data on each screen 113 for the screen 113 having the number of screen gaps A and B. A first to fifth step of controlling illuminance of the outer region irradiated from the light of the optical engine 114 formed on the side by a predetermined amount; Screen gap extraction method based on the display wall further comprises.
The method according to claim 6, wherein in the first step 1-5,
Each light of the optical engine 114 is formed of an assembly of a plurality of light emitting elements, or has a dimming function for controlling the illuminance of the peripheral area that is distinguished from the center constituting the light based on the display wall Screen gap extraction method.
The method of claim 6, wherein the first step,
After the above steps 1-5, the screen gap extraction module 124 has a vertical angle for adjusting the irradiation angle of the optical engine 114 with respect to each of the screens 113 having two screen gaps A and B. For the horizontal angle, the number of screen gaps (A, B) is 4 based on the "position shape information" analyzed in the above steps 1-3. First to sixth steps to face toward the center point of the rectangular shape formed by the personal screen 113; Screen gap extraction method based on the display wall further comprises.
The method of claim 8, wherein in the first to sixth steps,
The screen gap extraction module 124 controls the vertical irradiation angle and the horizontal irradiation angle with respect to each of the screens 113 having two and three screen gaps A and B through the reflection plate 112. The number of screen gaps A and B is the reflected light PL that forms the screen gaps A and B visualization areas among the plurality of reflected light PLs irradiated from each of the optical engines 114 for projecting image data. The display wall-based screen gap extraction method characterized in that the control is directed toward the center point of the rectangular shape formed by the four screen (113).
10. The method according to claim 9,
The screen gap extraction module 124 receives the captured image data on the image screen implemented in the display wall 100 by the external camera 200 through short-range wireless communication, and performs a screen gap through image recognition. A, B) After analyzing the image state, and extracts the screen 113 in which there is an area that is not removed from the screen gap (A, B) image of the entire screen 113 of the display wall 100 Step 2-1; Display gap based screen gap extraction method comprising a.
The method of claim 10, wherein the second step,
After the step 2-1, the screen gap extraction module 124 is perpendicular or horizontal to the reflecting plate 114 formed on the rear surface of each of the at least one or more screens 113 extracted by the step 2-1. Step 2-2 to perform the angle adjustment to; Screen gap extraction method based on the display wall further comprises.
The method according to claim 11, wherein the second step 2-2,
Each of the reflector plates 114 formed on the rear surface of the screen gap extraction module 124 increases the illuminance of each of the optical engines 114 to an unremoved region of the extracted screen gaps A and B. A display wall-based screen gap extraction method characterized in that for controlling to perform an angle control for.
A screen 113 of N (rows) by M (columns), which is the screen group 110 constituting the display wall 100;
An optical engine 114 formed on a rear surface of each of the screens 113; And
The screen gaps A and B may be controlled by controlling the illuminance, the vertical irradiation angle, and the horizontal irradiation angle according to the number of screen gaps A and B of each of the screens 113 with respect to each of the optical engines 114. Optical engine projection light adjusting means (124c) for reproducing the image screen implemented in the removed state for the visualization area; Display wall-based screen gap extraction system comprising a.
The method according to claim 13,
Reflector angle control means for removing the visualization area of the screen gaps A and B not removed by the first step by adjusting the angle of the reflector plate 112 formed on the back surface of each of the screens 113 ( 124f); Display wall-based screen gap extraction system further comprises a.

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