RU2557070C1 - Device for displaying video on composite liquid crystal screen - Google Patents

Abstract

FIELD: physics.SUBSTANCE: disclosed device for displaying video on a composite liquid crystal screen, which additionally includes: a LED panel switching and control unit connected to video processors of separate liquid crystal displays, and in the gaps between two separate adjacent liquid crystal screens on the vertical and the horizontal there are LED panels on the surface of the gaps, said panels having three-colour RGB LEDs, the emission of which is directed towards the viewing side of the image of the composite screen, wherein in the gaps on the vertical between two adjacent screens, the number of which is equal to M-1, the video information of the last column of the previous display is displayed, where M is the total number of liquid crystal displays placed on the horizontal, and in the gaps on the horizontal between two adjacent screens, the number of which is equal to N-1, the video information of the last row of the previous display is displayed, where N is the total number of rows on the vertical of horizontally placed liquid crystal displays, and the total number of the three-colour RGB LEDs used in the gaps on the vertical and horizontal is a number m=Y/d and n=X/d, where Y and X denote the linear dimension of the separate liquid crystal screen on the frame (vertical) and row (horizontal), d is the diameter of the separate RGB LED.EFFECT: high quality of display and comfortability of viewing video on composite liquid crystal screens.2 cl, 3 dwg

Description

The invention relates to means for displaying information for collective use, which allow several separate television and computer images or with a higher resolution image of one of them to be displayed on a composite screen. Video information can be presented in black and white, color or spectrozonal version in the form of real images or images in conventional colors, individual data, graphs, electronic maps, etc.

Such information display tools have practical applications for solving various tasks of video surveillance and object management in astronautics, in transport (railways, urban transport, shipping, aviation), in industry (oil, gas, chemical, etc.), in the telecommunications industry, in nuclear power plants, electric power industry and other industries.

They can be used in special monitoring systems, conference rooms of a high representative level, in centers for operational management of strategic facilities, in situational centers of ministries and departments, for municipal and state administration with video-conferencing sessions. They are necessary in crowded places at train stations and airports, during sporting events, in trade showrooms, in control rooms, in exhibition activities, in the leisure and entertainment industries, in show business, etc.

Display devices on a large composite screen can be of various types, each of which is characterized by the video display technology used. They include separate video information display devices (cathode ray tubes, projection modules, liquid crystal screens, plasma and LED screens, etc.), combined using the system of their mutual fastening in the so-called "video cube". Further, several such video cubes are joined together with small gaps and form the so-called "video walls" or a set of video cubes. By connecting several such video cubes into one system horizontally and vertically, they form a matrix of the form (MN), where in fact the number of separate modules for implementing a composite screen horizontally and vertically can take the values M, N = 1,2,3, ... S, where N is the number of vertical rows containing M-individual screens horizontally.

Moreover, the total number of modules can be equal, for example, 2 × 2, 3 × 3, 4 × 4, 1 × 3, 2 × 5, etc. Their number is selected from the condition of ensuring the required information capacity of the device and the resolution of the information display system, based on the tasks of monitoring, control and management of objects.

Whereas for a single screen, uniformity at all its points in brightness is not so important for the viewer to perceive as, say, color rendering quality, then for a large composite screen they are critically important. Even slight deviations in these characteristics can lead to the fact that the multi-screen image will not be perceived as a whole.

Today, video display devices on a large composite screen, as a rule, provide image resolution with standard, high and high definition, with a diagonal of a separate screen from 40 to 84 inches or more.

A composite screen control device (multi-channel video processor) can form a single information field with a resolution equal to the sum of the resolutions of individual screens. For example,

the total resolution of the composite screen, assembled from modules with a resolution of 1920 × 1080 pixels, organized in a matrix M-N = 2 × 2, is 3840 × 2160 pixels (pixels). Using separate display modules with a certain resolution and organizing them into a single space, you can create composite screens (video wall) with significant resolution to the required detail (resolution on the ground) of the observed objects in the image.

It should be noted that one of the main disadvantages of devices and means of displaying information on a composite large screen is still the presence of a visible gap between the individual screen modules (in the form of black bars between the screens), which leads to a loss in the integrity of the visual perception of a single image. An important task in the design and creation of such video information display devices is the possibility of reducing to a minimum the size of the docking (visible gap) of individual screens in a composite screen [1-4].

Known projection device for television and computer images, according to the patent of the Russian Federation for invention No. 2364907, IPC G03B 21/00 [5]. This device achieves the solution of the problem of reducing the gap between fragments of a composite projection screen to 0.1 mm.

At the same time, the main disadvantage of this type of device was that the use of individual light sources in each projection module, which have a service life of only 2 to 3 thousand hours, is not effective. The lamps used are very expensive, their cost is 20-35% of the cost of the projector, which is very noticeable for long-term operation of such projectors. In addition, the use of projection modules for displaying video information requires a relatively large distance between the displaying composite translucent screen and the rear wall of the device, which affects the placement of such devices in rooms. This makes it difficult to

the distribution of display devices of this type, especially with small sizes of rooms (conference rooms), due to the limited free space, and due to this it is difficult to ensure the required temperature conditions for their operation, which affects the quality and performance characteristics of the entire projection device.

In recent years, various types of liquid crystal (LCD) monitors (displays) have been increasingly used, the main advantages of which are the small thickness and weight compared to projection devices of the translucent type. Nowadays, LCD technologies are the most promising, and the sales sector of such monitors is the fastest growing. The principle of operation of LCD displays is described in detail in [6] and it is based on the phenomenon of polarization of the light flux.

The construction of video information display devices on a large composite screen using a number of LCD displays to form a video wall was hindered by the rather thick external frames of individual displays (20-25 mm). The overall single image on the composite screen was checkered, and this significantly reduced the scope of application of video walls using LCD displays. In recent years, LCD displays with a very thin frame have been developed, as a result of which the total gap between the abutting screens (images) in the video wall can reach values from 5.0 to 7.3 mm. It should be noted that today some displays are 55 "in diagonal and higher and with HD resolution (1920 × 1080) [7, 8].

The closest in technical essence is a device for displaying video information on a composite liquid crystal (LCD) screen, including a source of multimedia signals, including signals of television and computer images, multi-channel switches and video servers, control units for autonomous and joint operation of LCD displays and their monitoring, a system their mutual fastening and

a set of LCD displays that display on the composite screen video from different video sources or with a higher resolution of one of them, a composite screen in which the gap between the individual screens is determined by the selected type of LCD [8]. A display device for video information on a composite liquid crystal (LCD) includes a set of (MN) LCD displays, where N is the number of rows of LCD displays vertically, each row of which contains M LCD displays horizontally, displaying video images from different video sources or with high resolution of one of them. A disadvantage of the known solution for the implementation of a large composite screen of (M-N) individual LCD displays is that it is difficult to further reduce the overall clearance between the abutting screens in the video wall. The presence of a visible gap between individual LCD screens, in the form of black bars, leads to a deterioration in the comfort of image perception and, first of all, manifests itself when one video source is displayed on the entire composite screen (video wall).

In FIG. 1 shows, for example, a real video image on a composite 2 × 2 LCD screen. As you can see, the black bars present in the video image between adjacent LCD screens impair image comfort and quality.

The technical result is to provide improved display quality and comfortable perception of video information on composite LCD screens when displaying a single image.

The technical result is achieved in that in a video information display device on a composite liquid crystal (LCD) including a source of multimedia signals, including television and computer image signals, multi-channel switches and video servers, control units for autonomous and joint operation of LCD displays and their monitoring, a system their mutual fastening and a set of LCD displays displaying on a composite screen video from different video sources or with a higher resolution of one of them, according but the invention in a video display device on the composite LCD

the screen introduced a switching unit and control the operation of LED panels connected to the video processors of individual LCD displays, and in the gaps between two separate adjacent LCD screens, vertically and horizontally, LED panels containing three-color RGB LEDs are installed on the surface of the gaps, the radiation is directed towards the visual image perception of the composite screen, and in the vertical gaps between two adjacent screens, the number of which is equal to M-1, video information is displayed last video column of the previous display, where M is the total number of LCD displays located horizontally, and in the horizontal gaps between two adjacent screens, the number of which is equal to LM, the video information of the last row of the previous display is displayed, where N is the total number of rows vertically horizontally arranged LCD displays, while for a composite LCD screen, the total number of tri-color LEDs used in the vertical and horizontal gaps is

m = Y / d and n = X / d

where Y and X are the linear size of an individual LCD screen by frame (vertical) and line (horizontal), d is the diameter of an individual RGB LED.

The device can be designed so that the switching and control unit of the LED panels is configured to transmit video information about the distribution of the amplitude values of the RGB video signals of the last row and last column from the video processors of the individual LCD displays.

In FIG. 2 shows a diagram of a proposed device for displaying video information on a composite LCD screen.

A device for displaying video information on a composite LCD screen, consisting of several separate screens forming a video wall, contains (Fig. 2) a composite LCD screen with a system for their mutual fastening which includes N · M individual LCD displays 1 ₁ , 1 ₂ , 1 ₃ and 1 ₄ (for the case of individual LCD screens E1 _1; E 1 ₂ , E 1 ₃ , E 1 ₄ ), a block of multi-channel switches and video processors 2, a switching and control unit for LED panels 3, a source of internal and external video signals 4, a control unit and monitoring 5. In FIG. 2 shows that vertical gaps (along the frame) are formed between

two LCD screens (E1 ₁ , E1 ₂ ) and (E1 ₃ , E1 ₄ ), and horizontal gaps (per line) between two LCD screens (E1 ₁ , E1 ₃ ) and (E1 ₂ , E1 ₄ ).

A video display device on a composite screen according to FIG. 2 includes separate LCD displays 1 ₁ , 1 ₂ , 1 ₃ and 1 ₄ , which, depending on the operating mode, are independent or common modules. Each LCD is capable of autonomously generating individual video images in a video wall, based on the signals received at their inputs from a source of internal and external video signals 4. In addition, the device can operate in a mode where a composite screen with full resolution of the video wall reflects an image of one source of video signals, for which from block 2 the inputs of the LCD displays 1 ₁ , 1 ₂ , 1 ₃ and 1 ₄ for this operating mode receive their control and information signals with the formation of video signals of the corresponding frequency The entire image.

As you know, the coordinated operation of all LCD displays is achieved through the use of special controllers (video processors) and block 2 software, which are a kind of interface between video sources and a video wall. They are intended for reception, processing, storage and display on a large screen (video wall) of various multimedia information, their output on separate screens formed by several LCD displays. Moreover, for each LCD display, depending on its location, the controller synchronously generates video signals of the corresponding part of the overall image. In addition, video wall controllers have the ability to display images on a video wall from various external sources (video cameras, computers, players, etc.). Depending on the dimension of the video wall containing (M · N) LCD displays, the controllers can support various a priori known options for displaying video information on a composite screen 2 × 2, 3 × 2, 2 × 3, 3 × 3, etc.

In FIG. Figure 3 shows a general view of a composite LCD screen with a total number of individual screens equal to the value (M · N = 2 × 2 = 4), where in the vertical and horizontal gaps between the individual LCD screens E1 _1, E1 ₂ , E1 ₃ , E1 ₄ there are three-color RGB LEDs having a certain diameter d, for example, equal to the gap between two adjacent LCD screens E1 _1, E1 ₂ , E1 ₃ , E1 ₄ . Designations: a composite LCD screen with a mutual mounting system (in Fig. 1, and Fig. 2 are not indicated by a separate position), a vertical LED panel 6, a horizontal LED panel 7, a separate tri-color RGB LED 8 on an enlarged scale. For a composite LCD screen, the total number of 8 RGB LEDs used in the vertical and horizontal gaps is

m = Y / d and n = X / d,

where Y and X are the linear size of an individual LCD screen E1 _1, E1 ₂ , E1 ₃ , E1 ₄ per frame and line, d is the diameter of the tri-color RGB LEDs 8, M is the total number of LCD displays located horizontally (M = 1.2 , 3, ..., S), and TV is the total number of rows of such displays vertically (N = 1,2,3, ..., K).

The intensity of the glow of three-color RGB LEDs in the gaps of the composite screen is controlled by switching unit 3. To control the operation of LED panels 6, 7, outputs a, 6, c and switching unit 3 receive control signals to the corresponding LED panels 6, 7. From block 2 of multi-channel switches and video processors, the first and second inputs of the switching and control unit 3 of the LED panels receive video information about the distribution of the amplitude values of the RGB video signal of the last line of the LCD displays 1 ₁ and 1 ₂ . The third and fourth inputs of block 3 receives video information about the distribution of the amplitude values of the RGB video signal of the last column of the LCD displays 1 ₁ and 1 ₃ .

The installation of LED panels 6, 7 in the gaps between two adjacent LCD screens vertically and horizontally in the places of their joining actually removes the black bars in the composite LCD screen, due to the glow in these

the gaps of the three-color LEDs 8 in accordance with the amplitude of the video signal of the image of the last row and last column. This principle of replacing images of black bars with images of LED panels of a separate row and column is based on a mutual correlation of the amplitude of the image signals from element to element and from row to row (which practically do not change). This thereby improves the display quality and the comfort of visual perception of video information.

The use of tri-color RGB LEDs 8 can reduce the pixel pitch to 4 mm or even less, thereby increasing the image resolution of the LED panels 6, 7 located in the gaps of the composite screen. The luminous intensity of LEDs can, in principle, be regulated in two ways: analog (the lower the current, the lower the brightness) and digital pulse-width. However, the first has significant drawbacks, since the brightness and emitted color of the LED is not proportional to the current. Therefore, to control the brightness of LEDs, pulse-width modulation of direct (nominal operating) current is most often used, changing the duty cycle of the oscillations.

The principle of operation and a description of the operation of individual blocks and nodes in terms of processing and displaying information on a composite screen can be found in the following works [1, 2, 5, 6, 7].

Information sources

1. Sadchikhin AV, Sozinov SB, Morozov A. Hardware-software systems based on domestic composite screens. Electronics: Science, Technology, Business. M., 2005, issue 8.

2. Lyubimov B.O. The problem of designing a situational center and the main directions of its solution. M: INION RAS, 2005 .-- 112 p.

3. Patent EP 0650295, MKI H04N 5/74, - publ. 07/21. 1999.

4. RF patent No. 2257602 of the Russian Federation, G03B 21/00. Projection device (options). - publ. July 27, 2005, Bull. 21.

5. RF patent No. 2364907, IPC G03B 21/00. Projection device for television and computer images / Vilkova NN, Lyubimov B.O., Gubko V.D., Lyubimov A.O., Sagdullaev Yu.S. - publ. 08/20/2009, Bull. Number 23.

6. Mukhin I.A. The development of liquid crystal monitors. Part 1 and 2 / Broadcasting. Television and broadcasting. M .: 2005, No. 2 and No. 4. S. 55-56 and S. 71-73.

7. Fish A. In general and in detail / World of Automation, No. 1 (3), February 2006

8. PC Week Review. Multi-screen systems. Specialist. April 2010 issue

Claims (2)

1. A device for displaying video information on a composite liquid crystal (LCD) screen, including a source of multimedia signals, including television and computer image signals, multichannel switches and video servers, control units for autonomous and joint operation of LCD displays and their monitoring, a system for their mutual mounting and a set of LCD displays that display on a composite screen video from different video sources or with a higher resolution of one of them, characterized in that the device is selected For video information on the composite LCD screen, a panel for switching and controlling the operation of LED panels has been introduced, connected to the video processors of individual LCD displays, and in the gaps between two separate adjacent LCD screens, vertically and horizontally, LED panels containing three-color RGB LEDs are installed on the surface of the gaps. which are directed towards the visual perception of the image of the composite screen, and in the vertical gaps between two adjacent screens, the number of which is M-1, about video information of the last column of the previous display is displayed, where M is the total number of LCDs arranged horizontally, and in the horizontal gaps between two adjacent screens, the number of which is N-1, video information of the last row of the previous display is displayed, where N is the total number of rows vertically horizontally located LCD displays, while for a composite LCD screen, the total number of tricolor LEDs used in the vertical and horizontal gaps is
m = Y / d and n = X / d,
where Y and X are the linear dimensions of an individual LCD screen by frame (vertical) and line (horizontal), d is the diameter of an individual RGB LED. 2. The device according to p. 1, characterized in that the switching unit and control the operation of the LED panels is configured to transmit video information about the distribution of the amplitude values of the RGB video signals of the last row and last column from the video processors of the individual LCD displays.

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