KR20230130237A - Display - Google Patents

Abstract

The present invention includes a back surface having an array of two or more electronic pixels, each of the two or more electronic pixels comprising an active pixel area and a total pixel area, and a front surface comprising an array of electro-optical elements, is fixed to the back side and the active pixel region of at least two of the two or more electronic pixels in the back side is on the display opposite the inner cell region of each of the corresponding at least two elements of the two or more electro-optical elements. It's about.

Description

display{DISPLAY}

The present invention relates to a display that can prevent image distortion.

LED stands for light-emitting diode and is a semiconductor device that converts electrical energy into light energy. LED has high luminous efficiency and can save electricity and achieve other effects compared to other light sources. And with a lifespan of about 50,000 hours, it can be used more efficiently for a longer period of time than existing lamps.

Carbon dioxide emissions are reduced by 31% compared to regular fluorescent lamps, no harmful gases such as mercury discharge gas are used, and there are no harmful wavelengths. LED, which offers eco-friendly and high-efficiency characteristics, can be said to be an icon representing the technological trend of modern and future society.

LEDs with low power and high output can be used as a light source in many different fields.

Looking at LED application fields, LEDs used as lighting devices can be used in vehicle lights, traffic lights, emergency exit lights, and light bulbs, and can also be used as a medium that can change brightness according to human sensibility by adjusting the illuminance as a decorative light. possible.

In the case of infrared, treatment devices can be made using the far infrared rays of medical devices, invisible security detectors have been developed as security devices, and a large amount of image information can be transmitted and received due to the establishment of a high-speed optical communication network.

In addition, ultraviolet rays can be used to grow agricultural products instead of the sun as a growth energy light source for genetic engineering, and can also be used as a sterilization and disinfection light source. In this way, LED will become the energy driving force of future industries through its application in various fields rather than as a general light source.

Current trends in LED application product development are rapidly evolving. Considering its applicability and applicability in various fields, the added value of LED will grow into a competitive product that will become a center not only in the industrial economy but also in the global market. Additionally, the potential of the LED-related market is expected to continue to increase.

In particular, among many application fields, the LED display field is one that has a very large overall market size and ripple effect on other businesses.

Currently, LED display boards are installed not only indoors but also outdoors throughout buildings and are widely used to provide information to a large number of people.

Recently, the rate of exposure of LED electronic signs to various media outlets is increasing significantly, and in particular, the frequency of exposure through broadcast cameras is increasing.

In particular, in the case of HD broadcast cameras, images are captured and stored at a speed of hundreds to thousands of Hz, which is variable depending on the image size. However, in the case of general LED signboards with low LED image output speeds, distortion of the playback image may occur during camera shooting. You can.

Republic of Korea Patent Publication No. 1019980014561 (published on May 25, 1998)

The purpose of the present invention is to provide a display that maintains high resolution by eliminating the moiré phenomenon of LED images.

A display of the present invention includes a back side having an array of two or more electronic pixels, each of the two or more electronic pixels comprising an active pixel area and a total pixel area, and a front side containing an array of electro-optic elements, The front surface is fixed to the rear surface and the active pixel region of at least two of the two or more electronic pixels in the back surface is disposed opposite the inner cell region of each of the corresponding at least two elements of the two or more electro-optical elements. It can be.

In addition, the display further includes a plurality of virtual driver modules for controlling a plurality of virtual pixels to increase resolution, and the virtual pixels are located between rows of the plurality of rows formed by the first unit pixel and the second unit pixel. The pixels are set across, and the plurality of virtual driver modules can control the driving of each virtual pixel.

In addition, a driver module that drives the first unit pixel and the second unit pixel, a memory that stores each position to drive the virtual pixel, and a virtual pixel at the position stored in the memory to be displayed on the electronic signboard according to the input image are driven. It may include multiple virtual driver modules.

The present invention can increase resolution by narrowing the distance between LEDs provided in neighboring pixels by eliminating the moiré phenomenon that appears in LED images, and maintain higher resolution by multi-scanning the pixels.

In addition, the present invention provides a multi-LED display device and a manufacturing method thereof through a design and manufacturing method of an LED image display device, and provides a wiring structure that prevents mutual interference within a connector panel on which data lines and power lines are mounted. can be provided.

1. Elimination of moiré phenomenon that appears in LED images

Moire is a term derived from the French word for ‘wavy pattern’. If lines or figures of the same shape and thickness are drawn at regular and regular intervals on a transparent plate and overlapped in two layers, and the previous pattern is slightly moved, light interference occurs and a wave-shaped pattern appears.

This pattern is the effect of a type of intensity interference using an incoherent light source. Not only does the moiré pattern appear much larger than the original grid pattern, but its movement is often much faster than that of the grid, so it is widely used in industry such as subtle displacement or rotation, distortion of curved surfaces, and recognition of the three-dimensional shape of an object, as well as imitating the interference of waves. It is widely used for this purpose.

Displays are often assembled from the front, where the display's electro-optical cells are located, and the back, which contains the array of pixel electrodes and conductors for driving the electronics.

One of the final processing steps in manufacturing this type of display, for example Xiaojia Wang, is to create the cells of the display by stacking or other assembly of the front and back.

The active pixel area is the area of the back pixels that are available for the display itself and does not include the area of pixels that do not change their optical or electrical state during operation of the display. Examples of areas not included within the active pixel area are pixel row and column electrodes and thin film transistors (TFTs).

Each display element of the display thus has an aperture that can be defined as the entire interior area on the front side over the active pixel area divided by the entire area of its corresponding pixels on the back side (total pixel area).

By constructing a noise-resistant high-speed serial-parallel cascade data transmission device and improving the pixel structure of the conventional multi-scan LED signboard, we overcome the limitations of external and structural resolution and use the existing multi-scanning method or the existing dual scanning method. The purpose is to provide an LED display board that can achieve greater resolution compared to processing methods.

In other words, by changing the arrangement of the pixels, the distance between LEDs provided in neighboring pixels can be narrowed to increase resolution, and the purpose is to provide an LED signboard that can maintain higher resolution by multi-scanning the pixels arranged in this way. do.

By efficiently arranging the LEDs that make up a pixel and reducing the gap between LEDs, physical resolution has been increased, but the LEDs of the physically arranged pixels are virtually rearranged to form multiple virtual pixels and control operation for each virtual pixel. Resolution can be increased by multi-scanning.

Each of the two or more electronic pixels constituted a rear surface having an array of electronic pixels as a display, a rear surface having an array of electronic pixels having an active pixel area and a total pixel area, and a front surface comprising an array of electro-optical elements.

The front side is fixed to the back side and the active pixel region of at least two of the two or more electronic pixels in the back side is opposite the inner cell region of each of the corresponding at least two elements of the two or more electro-optic elements and at least one of the two or more electronic pixels in the back side is They formed first and second display elements, respectively.

To further increase resolution, multiple virtual pixels are set and controlled with multiple virtual driver modules. A virtual pixel is a pixel set between rows among a plurality of rows made up of first unit pixels and second unit pixels, and is provided with third to fifth virtual driver modules to control these virtual pixels, and each virtual driver module Each controls the operation of two virtual pixels.

A driver module that drives the first unit pixel and the second unit pixel, a memory that stores each position to drive the virtual pixel, and a plurality of virtual drivers that drive the virtual pixels of the positions stored from the memory to be displayed on the electronic signboard according to the input image. The module was constructed.

In repeated pairs of first and second unit pixels adjacent above and below, one color LED is selected from the first unit pixel on the upper side, and the remaining two color LEDs are selected from the first and second unit pixels on the lower side, respectively. It can be configured as follows.

The goal is to provide a display module with improved manufacturing efficiency and a method of manufacturing the same. In order to achieve this research objective, a method of manufacturing a micro LED display module was created, in which a step of pressing a plurality of micro LEDs disposed on a substrate coated with an adhesive layer was created to electrically connect the plurality of micro LEDs to the substrate.

In the step of curing the adhesive layer, the adhesive layer can be cured while pressing the alternative micro LED. In addition, for this research purpose, in the micro LED display module manufacturing method, a step of applying an adhesive layer to the second region of the substrate adjacent to the position where the defective micro LED is placed among the plurality of micro LEDs coupled to the first region of the substrate was created. .

After applying the adhesive layer, the step of transferring the applied substrate from the first space where the adhesive layer is applied to a second space different from the first space may be further included.

Before the step of transferring the replacement micro LED, a step of aligning the replacement micro LED was created so that each of the plurality of electrode pads formed on the upper surface of the substrate and each of the plurality of connection pads formed on one side of the replacement micro LED faced each other.

The multi-scanning method is a method that improves resolution by 6 times through mutual sharing (top, bottom, left, right) of LEDs arranged in neighboring pixels. In existing similar technologies, it can only be applied as a dynamic method. Although it has not been implemented, it has the advantage of being applicable as a static method, so it can maintain the same brightness as when using a single scanning method and maintain the natural color brightness of the electric signboard.

In an electronic signboard consisting of a display unit and a main controller that transmits and controls image signals to the display unit, the first unit pixel is configured so that red, green, and blue LEDs are arranged in horizontal order within an equilateral triangle-shaped area.

The backlight includes a light guide and the structure is positioned on the same side of the film as the backlight and the film for use with a backlit display has a prism structure on one side.

The prism structure has a serpentine shape and the serpentine shape has an average amplitude and an average period, and the average amplitude and average period can be selected to reduce visible moiré interference.

The display may be a back-emitting display comprising a second film between the backlight and the light gating device, wherein the film has a prism structure on one side and the structure has a serpentine shape and is located on the same side of the film as the light gating device. You can.

2. LED video display device design and manufacturing method

There are currently quite a few methods and structures for mounting LEDs as display devices or implementing them as circuits, and one of them is the SMD (Surface Mount Device) type, which mounts LED packages on rigid printed circuit boards, and has been widely used. .

However, although this technology can guarantee the stability and durability of the product, it has the disadvantage of being bulky and heavy, as well as being expensive, not having a wide application range, and having poor heat dissipation function.

In addition, today, in order to enlarge display devices, multi-display devices consisting of a combination of unit display panels of a certain size are being developed.

At this time, PDP (Plazma Display Panel) and LCD (Liquid Crystal Display) are generally used as unit display panels, and recently, LED (Light Emmitting Diodes) and OLED (Organic Light Emmitting Diodes) have been developed and used.

A multi-display device is driven by a control signal input from a controller such as a PC (Personal Computer) and displays images corresponding to video signals input from an image input device such as a video or DVI (Digital Video/Visual Interactive).

The unit display panels that make up this multi-display device are such that when an image signal and a control signal input from an image input device and a controller are input to at least one of the unit display panels, the input signal is transmitted to the remaining unit display panels. Communication is made in the form of a link to enable communication.

It relates to a multi-display device that enables the transmission of video signals, control signals, and operating power between the connected unit display panels by connecting and combining the unit display panels. A multi-display device in which the unit display panels are connected to form a large screen. am.

As a result, there is no need to perform separate cable wiring and connection work for communication and power supply, which shortens the work period when installing a multi-display device. Additionally, there is no need to secure work space, so multi-display devices can be installed in various places. It works.

However, even if such a connector is formed, the number of data lines and power lines that must be provided in a unit display is considerable, and especially when implementing a multi-display device, the data lines and power lines must be arranged in a complicated manner, which may only show structural limitations. However, there is a problem that an electrical short may occur.

Therefore, in order to solve this problem, in a multi-LED display in which multiple LED displays operate simultaneously, the configuration is not only simplified by configuring multiple data lines and power lines into a single panel, but also multiple LED displays are connected through this. There is a need to develop a multi-LED display device and a manufacturing method for combining displays together.

In a multi-LED display in which multiple LED displays operate simultaneously, the configuration is not only simplified by configuring multiple complex data lines and power lines into a single panel, but also allows for the combination of multiple LED displays. An attempt was made to develop a multi-LED display device and its manufacturing method.

In addition, we developed a wiring structure to prevent mutual interference within the connector panel where data lines and power lines are mounted, and provided an adhesive structure between the connector panel and the LED display to develop connector panels and LEDs that can respond to flexible LED displays. Research was conducted on the composition and manufacturing method of the insulating material that provides the adhesive structure of the display and prevents mutual interference within the connector panel where the data and power lines are mounted.

The LED display manufacturing method includes forming a base circuit including a gate electrode, a gate insulating film, and an active layer on a substrate, forming an electrode layer to form a first electrode layer surrounding the base circuit and a second electrode layer spaced apart from the first electrode layer. It is composed of stages.

It consisted of an insulating layer forming step of forming an insulating layer to cover the entire first electrode layer, the second electrode layer, and the gap area between the first electrode layer and the second electrode layer, and to form a trench-structured LED array area in a partial area on the gap area. .

An LED array step of arranging the LEDs in the LED array area by applying an electric signal to the first electrode layer and the second electrode layer while supplying a fluid containing LEDs on the substrate, and removing the insulating layer and connecting both ends of the LEDs to the first electrode layer and the second electrode layer, respectively. It was configured to include an LED bonding step to bond to the second electrode layer.

The electrode layer forming step may include forming a first metal layer surrounding the base circuit and forming a first electrode layer and a second electrode layer by removing a portion of the first metal layer corresponding to the gap region.

The insulating layer forming step includes forming an insulating layer on the first electrode layer, the second electrode layer, and the gap region, and forming an LED array region by partially etching a portion of the insulating layer corresponding to a portion of the gap region. It can be configured.

The LED bonding step included applying photoresist on the insulating layer and the LED, and forming a photoresist pattern by removing portions of the photoresist corresponding to both ends of the LED.

Using a photoresist pattern as an etching mask, the lower portion of the LED is removed from the insulating layer, and metal is electrodeposited in the area where the insulating layer has been removed, so that both ends of the LED are connected to the first electrode layer and the second electrode layer, respectively. It can be configured to include the step of connecting and the step of removing all of the photoresist and insulating layer.

The LED display manufacturing method further includes an electrode forming step in which the first electrode layer and the second electrode layer are etched according to a predetermined pattern to form the first electrode, the second electrode, and the power electrode.

An LED display is partially attached to the object of the entire display to produce an image, and a physical structure is installed in other spaces. If necessary, the LED is turned off and when the magic beam projector displays the image, the LED display is used by the beam projector by reflective material. It becomes a screen and reflects the image displayed by the beamprojector.

In order to produce such images, the LED attachment surface configured at regular intervals and the remaining free space are coated with reflective material to reflect the beam by a reflection area equal to the area covered by the LED light, like an enlarged surface.

In fact, many of the buildings in the city center are open and used as resting spaces, and while considering the installation of new advertising media in these spaces, we are exploring new video performances using LED billboards and surrounding spaces.

If the results are applied to the advertising market and the space creation and composition market, this type of image directing method will become a general trend, resulting in the production of related products and derivative services, and will be used in the LED-related display industry.

It is about a multiple display that combines LED and reflective material, and the space between the LED modules of the LED signboard is filled with a material that reflects BEAM's light rays. By allowing the LED signboard to be used as a BEAM screen, we provide information on how to configure the existing LED signboard and the surrounding space into one display using the BEAM Projector.

It consists of a method of coating the non-LED portion of the existing LED video display with reflective material paint and a method of installing a half mirror that has both reflective and transmission effects on the front of the existing video display.

While maintaining the LED image implementation effect, the image of the beam emitted from the front of the display is provided to display a reflected effect. It may include a color conversion layer that emits light of a predetermined color by light generated from the light emitting layer, and an ion implantation area that defines the current injection area of each subpixel area may be formed in the second semiconductor layer.

Claims (3)

a rear surface having an array of two or more electronic pixels, each of the two or more electronic pixels comprising an active pixel area and a total pixel area; and
A front surface containing an array of electro-optical elements,
The front surface is fixed to the back surface and the active pixel region of at least two of the two or more electronic pixels in the back surface is opposite the inner cell region of each of the corresponding at least two elements of the two or more electro-optic elements. display. According to paragraph 1,
The display further includes a plurality of virtual driver modules for controlling a plurality of virtual pixels to increase resolution,
The virtual pixel is a pixel set between rows among a plurality of rows formed by first unit pixels and second unit pixels,
A display wherein the plurality of virtual driver modules control driving of each virtual pixel. According to paragraph 2,
A driver module that drives the first unit pixel and the second unit pixel, a memory that stores each position to drive the virtual pixel, and a plurality of drivers that drive the virtual pixel at the position stored in the memory to be displayed on the electronic signboard according to the input image. A display that includes a virtual driver module.