KR100904499B1 - Multi image display apparatus, panorama image display apparatus and display method using the same - Google Patents

Abstract

A multi-image display apparatus, a panorama image display device and multi-image display method using the same are provided to offer relatively large multi-images to an observer who is moving in a closed space, at the same time. A main controller(110) controls and manages a multi-image display apparatus(100). An image displayer(120) displays a plurality of images for a moving observer. The main controller controls and manages image displayers through an internal communication unit(112b) based on a control connection line which is connected parallel to the image displayers.

Description

Multi image display apparatus, panoramic image display apparatus and multi image display method using same {Multi image display apparatus, panorama image display apparatus and display method using the same}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a display device, and more particularly, to a display device capable of providing a multi image or a panoramic image to a moving observer and a display method using the same.

Existing advertisements focused on the media such as newspapers and broadcasting, and still take up the largest proportion. However, due to the development of technology and the expansion of the advertising market, various display devices for providing information and advertisement, etc. have been developed. Accordingly, recent advertisements attempt to reduce the distance to potential customers by using various methods and various devices such as advertisement panels and large billboards installed on the streets. Along with this, spaces used by many people, such as subways, are recognized as suitable spaces for providing advertisements, and many types of advertisements have been attempted.

Among the advertising methods currently used in the subway, those using display devices include large display boards or projection devices installed in station platforms and advertisements on monitors installed in subway cars. However, the advertising method through a monitor installed in each passenger vehicle, which is an advertising method in a moving subway car, requires a lot of installation and operating costs, but due to the size and difficulty of installation of the monitor, it is not exposed to many passengers.

Accordingly, there is a limitation in a method of providing an image such as an advertisement in a moving space such as a subway, and it is difficult to provide various information or advertisements. Therefore, only the advertisement method for installing the printed advertisement at a portion higher than the passenger's field of vision is still mainly used.

The technical problem to be solved by the present invention is to provide a display device that can provide a multi-image or a panoramic image in order to solve the above problems in providing an image such as information or advertising to a moving observer. have.

In addition, another technical problem to be solved by the present invention is to provide a display method that can provide a multi-image or a panoramic image in order to solve the above problems in providing an image such as information or advertising to a moving observer. There is.

In order to achieve the above technical problem, the present invention provides a multi-image display device and a panoramic image display device as follows.

The multi-image display apparatus according to the present invention includes an N image display unit arranged to be arranged and a main controller unit for controlling M images each consisting of F frames to be reproduced on the N image display units, provided that F, M, N is each a positive integer of 2 or more, F ≦ N, M ≦ N), and the main controller unit is the nth image display unit of the N image display units (where 1 ≦ n ≦ N and n is a positive integer). Each f-th frame of all M images (where 1 ≦ f ≦ F, f is a positive integer, n ≦ F is n = f, and n> F is f = n-aF, where a controls to display the positive integers sequentially, and the main controller controls the F frames constituting one of the M images to be sequentially displayed by one frame on the N images. , The N video display Moving in the direction from the N-th image display unit of the first image display unit may allow the viewer the plurality of image display by the after image effect to.

The image display unit may be a flat panel display device. In particular, the flat panel display device may include LCD, PDDP, OLED, or LED.

Alternatively, the image display unit may be an LED bar that sequentially displays image information of one frame in a horizontal direction.

The first image display unit further includes a speed sensor unit including a first speed sensor sensor spaced apart from the first image display unit in a direction opposite to the second image display unit, the main controller unit is detected by the speed sensor unit The display time of each frame reproduced by the N video display units may be controlled by reflecting the observed viewer's speed.

The speed sensor unit further includes a second speed sensor disposed between the N image display units, and the main controller unit reflects the observer's speed detected by the second speed sensor, and the second speed sensor It is possible to control the display time of each frame to be reproduced in the image display unit arranged on the moving direction side of the observer.

The N image display units are electrically connected to each other, and the frame start signal may be transmitted from the first image display unit to the Nth image display unit to match the time at which the N image display units start displaying one frame. have.

Alternatively, the N image display units are electrically connected to each other, and the n1 image display unit of the N image display units (where 1≤n1≤N-1, where n1 is a positive integer) is the m1th image of the M images. (Where 1 ≦ m1 ≦ M-1, and m1 is a positive integer), where f1 is a positive integer, and f1 is a positive integer, and n1 = f1 when n1 ≦ F , when f1 = n1-aF) when n1> F is displayed, the f1 + 1th frame of the m1th image is displayed on the n1 + 1th image display unit when the f1th frame of the m1 + 1th image is displayed. The frame start signal may be transmitted to start.

The main controller unit includes an external communication unit for allowing an external administrator to control the main controller unit through a network, wherein the N image display units each include a first buffer unit, and the main controller unit is displayed on the nth image display unit. Each f-th frame data of all M images to be transmitted may be transmitted to and stored in the first buffer unit of the n-th image display unit.

The N image display units each include a second buffer unit, and the second buffer unit of the nth image display unit receives and stores each f-th frame data of all the M images stored in the first buffer unit of the nth image display unit. The first buffer unit may include a nonvolatile memory device, and the second buffer unit may include a volatile memory device capable of faster operation than the nonvolatile memory device.

Alternatively, the multi-image display apparatus according to the present invention reproduces the N image display units arranged so as to be arranged from the first to the N th along the moving direction of the moving observer and the M images each consisting of F frames on the N image display units. And a main controller unit for controlling the control unit (where F, M, and N are each positive integers of 2 or more, and F ≦ N, M ≦ N), wherein the main controller unit is the n2th of the N image display units. When moving in front of an image display unit (where 1 ≦ n2 ≦ N-1, and n2 is a positive integer), the m2th image of the M images (where 1 ≦ m2 ≦ M-1, m2 is a positive integer f1 frame (where 1 ≦ f2 ≦ F-1, f2 is a positive integer, n2 ≦ F is n2 = f2, and n2> F is f2 = n2-aF) Where a is a positive integer) and then the observer moves in front of the n2 + 1th image display unit. In this case, the n2 th image display unit may display the f2 th frame of the m2 + 1 th image and the n2 + 1 th image display unit may display the f2 th frame of the m2 th image.

In addition, the panoramic image display apparatus according to the present invention is composed of N image display units and F frames arranged to be arranged, wherein the length in the first direction is greater than the length in the second direction perpendicular to the first direction. It includes a main controller for controlling to reproduce the wide panoramic image in one direction into M divided images to have a constant width in the first direction to be reproduced in the N image display unit (where F, M, N are each two or more) A positive integer, F ≦ N, M ≦ N), and the main controller unit divides the M divided images in the nth image display unit of the N image display units (where 1 ≦ n ≦ N and n is a positive integer). Each f-th frame of all (where 1≤f≤F, f is a positive integer, n = F for n = f, f = n-aF for n> F, where a is positive Integers) of the control unit to be displayed sequentially, and the main The controller controls the F frames constituting one divided image of the M divided images to be sequentially displayed by one frame on the N image display units, thereby being Nth from the first image display unit of the N image display units. The M divided images may be connected to the observer moving toward the image display unit and displayed as a panoramic image by the afterimage effect.

The N image display units are electrically connected to each other in series, and m1 of the M segmented images in the n1-th image display unit of the N image display units (where 1≤n1≤N-1, where n1 is a positive integer). F1 frame (where 1≤f1≤F-1, f1 is a positive integer, and n1 = f1) of the first divided image (where 1≤m1≤M and m1 is a positive integer) When n1> F, f1 = n1-aF) is displayed and the f1 + 1th image of the m1th divided image is displayed on the n1 + 1th image display unit when the f1th frame of the m1 + 1th divided image is displayed. The frame start signal may be sent to start displaying the frame.

In order to achieve the above technical problem, the present invention provides a multi-image display method as follows.

The multi-image display method according to the present invention comprises the steps of detecting the movement speed of the observer, displaying the current frame of the first image on the first image display unit when the observer is located on the first image display unit and the observer When the observer is positioned on a second image display unit adjacent to the first image display unit according to a moving direction of the display unit, the next frame of the first image is displayed on the second image display unit based on the detected movement speed. The first image display unit may include displaying a current frame of a second image different from the first image.

The multi-image display apparatus and method according to the present invention can provide a multi-image, which is a plurality of images, at a relatively large image size to an observer moving in a closed space such as a subway. In particular, it is possible to provide various kinds of images instead of one repeated image.

The panoramic image display apparatus according to the present invention can be provided to an observer who moves a panoramic image having a wide image width without a problem such as flickering even in an image having a large number of frames per second by configuring a large screen with a plurality of image display units.

In particular, regardless of the number of moving observers (vehicles, subway cars) by installing only a fixed device in a certain place to provide a multi-image or panoramic image, it is possible to provide an effective image display at a low cost.

In addition, it can be used in various places such as high-speed elevators, highway tunnels, and nighttime roads as opposed to the constant speed section, such as the underground section of the subway.

Hereinafter will be described in detail to enable those skilled in the art to easily understand and reproduce the present invention through the preferred embodiments. However, embodiments of the present invention illustrated below may be modified in various other forms within the scope of the same invention, and the scope of the present invention is not limited to the embodiments described below and the accompanying drawings. In the following description, when a component is described as being connected to another component, it may be directly connected to another component, and a third component may be interposed therebetween. In addition, in the drawings, the size and position of each component are exaggerated for convenience and clarity of description, and parts irrelevant to the description are omitted. Like numbers refer to like elements in the figures. On the other hand, the terms used are used only for the purpose of illustrating the present invention and are not used to limit the scope of the invention described in the meaning or claims.

1 is a schematic diagram illustrating a state in which a multi image display apparatus is installed according to an exemplary embodiment of the present invention.

Referring to FIG. 1, a multi-image display apparatus according to an exemplary embodiment includes a plurality of image display units 120 arranged to be arranged. The image display units 120 may use, for example, liquid crystal displays (LCDs), plasma display panels (PDPs), organic light emitting diodes (OLEDs), or light emitting diodes (LEDs). It may be a flat panel display device.

The image display units 120 may be installed in a dark or closed space, for example, a wall of a tunnel, a periphery of a subway track, and the like. Alternatively, the image display units 120 may be installed on the side of the road to be used in a dark time zone such as at night. The details will be described later. However, since the operation of the multi-image display device is convenient when the front of the image display unit 120 moves at a relatively constant speed, it may be most commonly installed on the wall of the underground operation section of the subway. However, it can be installed on the walls of tunnel sections on highways that are relatively long and have no heavy traffic.

Although illustrated, the image display units 120 are mainly arranged in a horizontal direction, but may be arranged so as to be arranged in a vertical direction on a wall surface of an elevator passage of a high-rise building.

2 is another schematic diagram illustrating a state in which a multi-image display apparatus according to an exemplary embodiment of the present invention is installed.

2, unlike the example illustrated in FIG. 1, the image display units 120 may be, for example, LED bars. LED bars can usually be configured by arranging LED pixels in a row. In this case, each LED pixel of the LED bar may include at least one individual LED element of three colors (Red, Green, Blue) in order to express full color.

3 is a schematic diagram illustrating a method of displaying an image using an LED bar used in an embodiment of the present invention.

Referring to FIG. 3, the LED bar used as the image display unit 120 scans and displays pixels constituting one frame of one image in units of lines in one direction. Therefore, when the scan is performed at an appropriate speed by the LED bar, the entire frame forming one screen can be seen with the afterimage effect. Of course, the effect of the afterimage may be greater as repeated by the plurality of image display units 120 arranged to be arranged as described above.

For example, if you want to display an image of 24 frames per second with a frame size of 1024 pixels x 768 pixels, one frame may be displayed for about 41.7 ms (1/24 sec). Therefore, the LED bar can display one frame by scanning 1024 lines for about 41.7 ms.

However, in the multi-image display apparatus according to the exemplary embodiment of the present invention, the LED bar itself does not move, but when the observer moves in front of the fixed LED bar, it looks like the LED bar is scanning and passing by. Therefore, the LED bar may scan in units of vertical lines when the observer moves in the horizontal direction, and scan in units of horizontal lines when the observer moves in the vertical direction.

4 is a schematic diagram illustrating a configuration of a multi-image display apparatus according to an exemplary embodiment.

Referring to FIG. 4, the multi-image display apparatus 100 may include a main controller 110 for controlling and managing the multi-image display apparatus 100 and a plurality of image display units for allowing a plurality of images to be viewed by a moving viewer. 120). The main controller unit 110 may include a main communication unit 112, and the main communication unit 112 may include an external communication unit 112a and an internal communication unit 112b.

The external communication unit 112a of the main controller unit 110 is connected to the management server 20 through a wired or wireless network 50 such as the Internet. Therefore, the external administrator may control and manage the main controller unit 110 through the network 50 using the management server 20. Therefore, the external manager can control and manage the multi image display apparatus 100 from the outside through the network 50.

The main controller unit 110 may control and manage the image display unit 120 by connecting the plurality of image display unit 120 and the control connection line in parallel through the internal communication unit 112b. The main controller unit 110 may be individually connected to the image display units 120 through the distributor 130. Dispenser 130 may be, for example, one or a plurality of hubs. The multi-image display apparatus 100 may include, for example, N image display units 120. The image display unit 120 receives the image data or the control signal to be displayed from the main controller unit 110 through the sub communication unit 122 from the first image display unit D1 to the Nth image display unit DN. The desired image can be shown to the observer 10 moving in front of the field.

For example, the observer 10 moving at a speed of 70 km / h moves about 19.4 m per second. Thus, for example, in order to reproduce an image having 24 frames per second, one frame must be displayed in a width of about 0.8 m or less. Based on this, the number of frames of the image to be displayed and the width of the image can be determined, and through this, the positions of the image display units 120 can be determined. For example, if there is an observer 10 moving at a speed of 70 km / h, if the image display unit 120 is disposed every 0.8 m, an image having 24 frames per second may be reproduced.

However, since the height of the image is not limited, it is possible to configure the height of one frame of the image in a size suitable for the observer to recognize. For example, when an image is provided to an observer traveling by subway in an underground section of the subway, the image display unit 120 may be arranged to match the height of the window of the subway to determine the height of the image.

5 is a schematic diagram illustrating a modified configuration of a multi-image display apparatus according to an exemplary embodiment.

Referring to FIG. 5, the main controller 110 included in the multi-image display apparatus 100 has a plurality of image display units 120 and a control connection line in series through the internal communication unit 112b, unlike the example illustrated in FIG. 4. Connected to control and manage the image display unit 120. The image display units 120 may be connected to the main controller 110 or other image display units 120 through the sub communication unit 122 including the first sub communication unit 122a and the second sub communication unit 122b, respectively. When the image display unit 120 is installed over a long distance, it is possible to prevent the difficulty of installation and maintenance by connecting in series.

6 is a schematic diagram illustrating a configuration and a control method of a multi-image display apparatus according to an exemplary embodiment.

Referring to FIG. 6, the multi-image display apparatus 100 further includes a speed sensor unit 150. The speed sensor unit 150 detects a first speed that is spaced apart from the first image display unit D1 at a position before the moving observer 10 among the image display units 120 moves forward of the first image display unit D1. It may include a sensor 152. In addition, the display apparatus may further include at least one second speed sensor 154 disposed between the plurality of image display units 120.

When the speed of the observer 10 moving around the multi-image display apparatus 100 is relatively constant, an image display method of the image display units 120 to be described later may be set in advance. However, when the speed of the moving observer 10 changes relatively, the speed of the observer 10 may be sensed to control the image display method of the image display units 120 in real time.

In this case, the frame start signal S _F is transmitted from the first image display unit D1 to the N-th image display unit DN by reflecting the speed detected by the speed sensor unit 150. The video display method can be controlled. As shown, the frame start signal S _F may be directly transmitted through a separate signal transmission line connecting the image display units 120 in series. However, as shown in FIGS. 4 to 5, the main controller unit 110 may transmit the frame start signal S _F through control connection lines for controlling the image display units 120.

The speed of the moving observer 10 is constant while moving in front of the image display unit 120, but if there is a difference in speed each time the moving observer 10 moves, the speed detection by the first speed sensor 152 is important. do. However, if the speed of the moving observer 10 changes even while moving in front of the image display unit 120, the second speed sensor 154 is also required together with the first speed sensor 152.

However, the speed sensor unit 150 is a matter of selection according to the flow of frames and images per second, and is not always necessary when the speed of the moving observer 10 changes. This will be described in detail later.

FIG. 7 is a table illustrating a method of displaying image frames over time in a multi-image display apparatus according to an exemplary embodiment.

4 to 7, the plurality of image display units 120 may control and display an image and a frame based on the moving speed of the observer 10. In the table shown in FIG. 7, the frame start time t ₀ to t ₅ is determined by the virtual moving observers (observer 1 to observer 3) spaced apart by an interval between adjacent image display units 120. ) Is the time when it is placed before the. For example, when the image display unit 120 is a flat panel display device, the frame start time t ₀ to t ₅ is the first time that the flat panel display device appears on the virtual moving observer (observer 1 to observer 3). It's time. Also, for example, when the image display unit 120 is an LED bar, a frame start time t ₀ to t ₅ is a time point at which the LED bar is positioned on the virtual moving observers (observers 1 to 3). In addition, MX _FY means the Y-th frame of the X-th image.

Observer 1 is positioned on the first image display unit D1 at a time t = t ₀ , where the first image display unit D1 displays the first frame M1 _F1 of the first image. When the observer 1 moves and is positioned on the second image display unit D2 at a time t = t ₁ , the second image display unit D2 displays the second frame M1 _F2 of the first image. Also, observer 2 is positioned on the first image display unit D1 at a time t = t ₁ , where the first image display unit D1 displays the first frame M2 _F1 of the second image. Here, observer 2, which is a virtual observer, may be a separate observer from observer 1, or may be a previous image display unit in the observer 1's field of view. That is, when the observer 1 is positioned on the second image display unit D2, it may mean the first image display unit D1 seen in the observer 1's field of view. It may be to watch.

By repeating the above process, observer 1 can see successive frames M1 _FY of the first image, and observer 2 can see successive frames M2 _FY of the second image. Thus, for example, three image display units 120 may be simultaneously visible to the moving observer 10 's field of view, or the moving observer 10 may turn to the eye at one point in time to view up to three image display units 120. If present, the moving observer 10 can view three different images at the same time.

The implementation method of the multi-image display apparatus 100 is summarized as follows. For example, the N image display units 120 are arranged so that the observer 10 moves from the first image display unit D1 toward the Nth image display unit DN, and each of the F frames is composed of M frames. Can be controlled by the main controller 110 so that the N images are reproduced on the N image display units (where F, M, and N are each positive integers of 2 or more, and F≤N, M≤N).

In the n-th image display unit (Dn, where 1 ≦ n ≦ N and n is a positive integer) of the N image display units 120, each f-th frame of all the M images (where 1 ≦ f ≦ F and f is A positive integer, if n ≦ F, n = f, and if n> F, f = n-aF, where a is a positive integer). Therefore, F, the number of frames of the M images, is preferably equal to or smaller than N, the number of the image display unit 120. In addition, in consideration of the number of images simultaneously displayed on the N image display units 120, it is preferable that M, the number of images, is equal to or less than N, the number of image displays 120. In addition, when F, the number of frames of each of the M images, is less than N, the number of the image display unit 120, the F + 1th image display unit 120 reproduces the first frame of each image to reproduce the same image repeatedly. Can be.

In addition, the F frames constituting one of the M images are sequentially displayed by one frame on each of the N image display units 120, so that the direction of the N-th image display unit DN from the first image display unit D1 is achieved. The observer 10 moving to may see that the frame of the same image is changed and reproduced as an image at a specific gaze by the afterimage effect.

Through this, it is possible to implement a multi-image display apparatus that simultaneously displays a plurality of images, for example, M images.

6 and 7, when the moving observer 10 is detected by the first speed sensor 152, the observer 10 may view the first image based on the detected moving speed of the observer 10. When reaching on the display unit D1 (t ₀ ), the first frame M1 _F1 of the first image is displayed on the first image display unit D1. When the observer 10 moves at a constant speed, the frame start signal S _F is transmitted to the other image display units D2 to DN, so that the other image display units D2 to DN simultaneously display the image with the first image display unit D1. Can be displayed. In addition, the frame start signal S _F may be repeatedly transmitted based on the detected speed of the observer 10 so that the image display unit 120 repeatedly displays the next frame of the current frame. In addition, when the moving speed of the observer 10 changes, the frame start signal S _F may be transmitted by reflecting the moving speed detected by the second speed detecting sensor 154.

As such, when the image display method is adjusted in consideration of the moving speed of the observer 10, the moving observer 10 may view a plurality of images reproduced at a fixed position. However, when the moving speed of the observer 10 changes a lot, the frames per second of each image may change, and thus the playback speed of the image may change. Therefore, in this case, the frame of the image displayed on the image display units 120 may be adjusted based on the initially detected movement speed or the predetermined movement speed without considering the change in the movement speed of the observer 10. In this case, although the position of the image shown may move somewhat according to the moving speed of the observer 10, the images may be reproduced at a constant frame per second. Accordingly, in consideration of the change in the moving speed of the observer 10, an efficient method may be selected between the position change of the image shown to the observer 10 and the change of frames per second.

For example, when the moving speed of the observer 10 is always constant, the frame of the image displayed on the image display units 120 may be controlled according to a preset method. In this case, the first speed sensor 152 may be used to detect the observer 10 and determine a time point at which the image display unit 120 starts to display an image.

Or, for example, if the moving speed of the observer 10 is not always constant but there is little change in speed during movement, the image displayed on the image display units 120 based on the speed detected by the first speed sensor 152. You can control the frame. However, when the movement speed is severe enough that the frame change per second of the reproduced image is severely felt by the observer 10, the frame per second may be controlled to be relatively constant even if the position of the image moves slightly.

FIG. 8 is a table illustrating another method of displaying image frames over time in a multi-image display apparatus according to an exemplary embodiment.

Referring to FIG. 8, the plurality of image display units D1 to D6 may start displaying an image in consideration of the movement of an observer. For example, when the image is displayed when the subway moves in the underground operation section of the subway, it is not necessary to drive the image display units D1 to D6 while the subway does not move. Therefore, the image can be displayed only while the subway starts moving and passes on each image display unit D1 or D6.

For example, if imaginary moving observers (observers 1 to 3) are passengers in the subway and observer 1 is at the forefront of the subway, each image display unit D1 or D6 is viewed by observer 1. The image can be displayed only when or before. Although not shown, the display of the image may be stopped when or after the observer who is riding at the rear of the subway cannot see each image display unit.

6 and 8, the speed sensor unit 150 detects the observer 10 and the moving speed so that the virtual observer 1, that is, the moving observer 10, is first displayed on the first image display unit D1. When it is positioned (t ₀ ), the first image display unit D1 starts displaying the first frame M1 _F1 of the first image. Then, when observer 1 is positioned on the second image display unit D2 (t ₁ ), the second image display unit D2 starts to display the second frame M1 _F2 of the first image, and simultaneously The first frame M2 _F1 of the second image is displayed on the image display unit D1. Through this, the time for displaying images on the plurality of image display units 120 may be minimized, thereby minimizing device operating costs such as power costs.

This is summarized as follows. The m1-th image of the M images (where 1≤m1≤M-1) in the n1-th image display portion (Dn1, where 1≤n1≤N-1, where n1 is a positive integer) among the N image display portions 120. Where m1 is a positive integer, where 1 ≦ f1 ≦ F-1 and f1 is a positive integer; n1 ≦ F, n1 = f1, and n1> F, f1 = n1 -aF), i.e., after displaying m1 _f1 and starting to display the _f1 frame of the m1 + 1 th image, that is, m1 + 1 _f1 , the m1 th image on the n1 + 1 th image display unit (D (n1 + 1)) The frame start signal may be transmitted to start displaying the f1 + 1 th frame of m, that is, m1 _{f1 + 1} .

9 is a schematic diagram illustrating a configuration of an image display unit according to an exemplary embodiment of the present invention.

Referring to FIG. 9, the image display units 120 may include a buffer unit 124 and an image module 128, respectively, and the buffer unit 124 may include a first buffer unit 124a. The imaging module 128 may be an LCD, a PD, an LED or an LED on which an image is actually displayed. The image data transmitted from the outside, that is, the main controller unit 110 (FIGS. 4 to 6) is stored in the first buffer unit 124a through the sub communication unit 122, and the image data stored in the first buffer unit 124a is stored. It may be displayed on the imaging module 128. In this case, each of the image display units 120 may store only the frames to be displayed on the image display unit 120 among the plurality of images to be displayed on the multi-image display apparatus in the first buffer unit 124a.

In addition, the buffer unit 124 may further include a second buffer unit 124b. In this case, the second buffer unit 124b may include a memory device capable of a faster operation than the first buffer unit 124a. Image data transmitted from the main controller unit and stored in the first buffer unit 124a may be stored again in the second buffer unit 124b for display on the actual image module 128. As a result, each image display unit 120 may have a space for storing frames to be displayed and a space for reproducing when the frames are changed at a high speed.

For example, the first buffer unit 124a may include a nonvolatile memory device such as a flash memory, and the second buffer unit 124b may include a dynamic random access memory (DRAM) or a static RAM (SRAM). And a volatile memory device such as Random Access Memory. However, the type of memory elements constituting the first buffer section 124a and the second buffer section 124b is not limited thereto. That is, the first buffer unit 124a can use any memory device that can store stored image data regardless of whether power is supplied or not, and the second buffer unit 124b performs fast frame conversion regardless of volatile / non-volatile characteristics. To this end, any memory device capable of high speed operation may be used. Therefore, in the case of a memory device capable of both nonvolatile and high-speed operation, it is possible to configure only the first buffer unit 124a without using the second buffer unit 124b.

10 is a view showing the implementation of the multi-image display device according to an embodiment of the present invention.

Referring to FIG. 10, in a multi-image display apparatus according to an exemplary embodiment, a moving observer may simultaneously view two or more images. In particular, in a section in which the constant velocity movement is performed, the visible image may be viewed at a fixed position without flowing from side to side even though the observer moves. In addition, although a case in which different images are played together is shown, one image may be divided into a plurality and then played together.

4 and 10, the panorama image of one wide direction in the management server 20 is separated along the wide direction and sent to the main controller unit 110 as a plurality of separate images, or in the management server 20. The received panorama image may be separated from the main controller unit 110 to form a plurality of images. For example, the panoramic image means that the width direction is longer than the height direction perpendicular to the width direction, and in particular, the width direction is wider than the image that can be displayed on one image display unit 120. When the panorama image is separated and played back in sequence on the adjacent image display unit 120, the multi image display apparatus 100 may be used as the panorama image display apparatus.

As described above, in the case of providing 24 frames per second to an observer moving at 70 km / h, the width of one frame is limited to 80 cm. Therefore, when displaying an image having a wider width than that, it is impossible to display a natural video such as flicker. However, for example, in the multi-image display apparatus 100 that reproduces M images together, when the panorama images are divided into M and reproduced, the panorama image having a width M times wider can be reproduced.

1 and 2 are schematic views illustrating a state in which a multi-image display apparatus according to an exemplary embodiment of the present invention is installed.

3 is a schematic diagram illustrating a method of displaying an image using an LED bar used in an embodiment of the present invention.

4 to 5 are schematic diagrams illustrating a configuration of a multi-image display apparatus according to an exemplary embodiment.

6 is a schematic diagram illustrating a configuration and a control method of a multi-image display apparatus according to an exemplary embodiment.

7 to 8 are tables illustrating a method of displaying image frames over time in a multi-image display apparatus according to an exemplary embodiment.

9 is a schematic diagram illustrating a configuration of an image display unit according to an exemplary embodiment of the present invention.

10 is a view showing the implementation of the multi-image display device according to an embodiment of the present invention.

<Description of main parts of drawing>

100: multi-image display device, 110: main controller portion, 120: image display portion, 124: buffer portion, 130: distributor, 150: speed sensor portion

Claims (14)

delete delete delete delete delete delete delete delete delete delete N image display units arranged to be arranged at predetermined intervals from the first to the N-th along the moving direction of the moving observer; M partitions, each of which is composed of F frames and has a constant width in a first direction, of a wide panoramic image in the first direction having a length in a first direction greater than a length in a second direction perpendicular to the first direction. A main controller unit which divides the image into the N video display units and controls them to be reproduced on the N video display units (where F, M, and N are each positive integers of 2 or more, F ≦ N, M ≦ N), The main controller unit is an nth image display unit of the N image display units (where 1 ≦ n ≦ N and n is a positive integer) for each f-th frame of all the M divided images (where 1 ≦ f ≦ F). f is a positive integer, n = f for n≤F, f = n-aF for n> F, where a is a control to display sequentially) The main controller controls the F frames constituting one divided image of the M divided images to be sequentially displayed by one frame on the N image display units. And the M divided images are successively displayed as a panoramic image by an afterimage effect to an observer moving toward the Nth image display unit from the first image display unit among the N image display units. The method of claim 11, wherein The N image display units are electrically connected to each other in series. The n1-th image display unit of the N image display units (where 1≤n1≤N-1, where n1 is a positive integer), and the m1-th division image of the M divided images (where 1≤m1≤M, m1 Is a positive integer f1 frame (where 1 ≦ f1 ≦ F-1, f1 is a positive integer, n1 ≦ F is n1 = f1, n1> F is f1 = n1-aF, Where a is a positive integer) and then the frame starts to display the f1 + 1th frame of the m1th split image on the n1 + 1th video display unit when the f1th frame of the m1 + 1th split image starts to be displayed. A panoramic image display device, characterized by transmitting a start signal. delete delete

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