KR102463998B1 - Micro led display device - Google Patents

Abstract

The present invention relates to a microLED display device capable of preventing core defects. The first R, G, and B microLEDs outputting G and B color light, and disposed in each pixel area of the display panel to output R, G, and B color light, from the first R, G, B microLED It consists of 2R, G,B microLEDs spaced apart in the vertical direction, and drives the main light emitting microLEDs of the 1R,G,B microLED and the 2R,G,B microLED to realize an image and a plurality of tiled When the distance between the display panels exceeds a set value, the auxiliary light emitting microLEDs of the first R, G, and B microLEDs and the second R, G and B microLEDs in the pixel area of the boundary area are additionally driven.

Description

MICRO LED DISPLAY DEVICE

The present invention relates to a microLED display device capable of preventing heart failure.

Since the development of an organic electroluminescent device using poly(p-phenyllinevinyline) (PPV), which is one of the conjugated polymers, research on organic materials such as conductive conjugated polymers has been actively conducted. Research for applying these organic materials to thin film transistors, sensors, lasers, and photoelectric devices is also in progress, and among them, research on organic light emitting display devices is being conducted most actively.

In the case of an electroluminescent device made of phosphors-based inorganic materials, an operating voltage of 200 V or higher is required, and the manufacturing process of the device is made by vacuum deposition. have. However, the electroluminescent device made of organic material has the advantages of excellent luminous efficiency, facilitation of large area, process simplicity, and in particular, the advantage of easily obtaining blue light emission. It is in the spotlight as a display device.

Currently, an active matrix organic light emitting display device having an active driving element in each pixel like a liquid crystal display device is being actively studied as a flat panel display device.

However, such an organic light emitting display device has the following problems.

In general, an organic light emitting display device deposits an organic light emitting layer on a substrate using a fine metal shadow mask. However, in the process using such a metal shadow mask, there is a limit to forming a large-area organic light emitting display device. In addition, in the case of a high-resolution display device, a metal shadow mask must be manufactured with a high resolution, but there is a limit to the production of the metal shadow mask.

In order to solve this problem, an organic light emitting display device in which a white light emitting device and a color filter are combined has been proposed. In such a white organic light emitting display device, the amount of organic material used is small, the process time is short, the yield is high, and the cost is reduced. However, in the white organic light emitting display device, luminance is lowered due to light absorption by the color filter and color purity is lowered. In addition, there is still a limit to manufacturing a large-area display device.

The present invention has been made in view of the above points, and an object of the present invention is to provide a microLED display device having a microLED.

Another object of the present invention is to provide a microLED display device capable of preventing a seam from being displayed on a screen due to a tiling error when tiling a plurality of microLED display panels.

The microLED display device of the present invention includes a plurality of display panels each including a plurality of pixel regions and tiled at a predetermined tiling interval, and is disposed in each pixel region of the display panel to output light of R, G, and B colors. first R, G, and B microLEDs, which are disposed in respective pixel areas of the display panel to output light of R, G, and B colors, and are disposed vertically spaced apart from the first R, G, and B microLEDs Consists of 2R, G, and B microLEDs, driving the main light emitting microLEDs of the first R, G, B microLED and the second R, G, B microLED to realize an image, and spacing between a plurality of tiled display panels When this set value is exceeded, the auxiliary light-emitting microLEDs of the first R, G, and B microLEDs and the second R, G, and B microLEDs in the pixel area of the boundary area are additionally driven.

When the main light-emitting microLEDs are the first R, G, and B microLEDs arranged in a line, the auxiliary light-emitting microLEDs in the pixel area adjacent between the vertically spaced microLED display panels are the second R, G, and B microLEDs, Auxiliary light emitting microLEDs in pixel areas adjacent to each other between the microLED display panels spaced apart in the horizontal direction are arranged in one R, G, B arrangement in two pixel areas among the second R, G, B micro LEDs in two adjacent pixel areas. It is a microLED that is additionally driven by

When the main light emitting microLEDs are microLEDs arranged in a delta (Δ) shape among the first R,G,B microLEDs and the secondR,G,B microLEDs arranged in a line, between the microLED display panels spaced apart in the vertical direction The auxiliary light emitting microLED in the pixel region adjacent to the boundary region of It is a microLED that is additionally driven in a shape, and the auxiliary light emitting microLED in the pixel area adjacent to the boundary area between the horizontally spaced microLED display panels is one microLED among the 1R, G, and B microLEDs in the pixel area and One microLED among the second R, G, and B microLEDs in the adjacent pixel area. Also, in this case, the auxiliary light emitting microLEDs in the pixel region adjacent to the boundary region between the horizontally spaced microLED display panels are the first R, G, and B microLEDs in the corresponding pixel region and the second R, G in the pixel region adjacent to the microLED display panel. ,B It is a microLED that is additionally driven in one delta (Δ) shape or inverse delta (▽) shape in two pixel areas among microLEDs.

When the main light emitting microLEDs are microLEDs arranged in an inverse delta (▽) shape among the 1R, G,B microLEDs and 2R,G,B microLEDs arranged in a line, the microLED display panel spaced apart in the vertical direction The auxiliary light emitting microLED in the pixel region adjacent to the boundary region between the two pixel regions has one inverse delta ( It is a micro LED that is additionally driven in the shape of ▽).

The present invention further includes a data correction unit for correcting the color and luminance of the auxiliary light emitting microLED, wherein the data correction unit includes a compensation value generating unit for generating a compensation value based on image data of a photographed screen, and from an external system. It consists of a data modulator that modulates input image data according to the generated compensation value, and a filter unit that filters input image data modulated by the data modulator.

In the present invention, since a display device is manufactured by simply transferring a microLED made of an inorganic material onto a large-area substrate, a large-area display device with high luminance, long lifespan, and low cost can be easily manufactured.

In addition, in the present invention, when tiling a plurality of microLED display panels, the redundancy microLEDs are vertically spaced apart from the main light emitting LEDs by a predetermined distance, and when a tiling error occurs, the redundancy microLEDs are driven by driving the redundancy microLEDs according to the tiling error. defects can be prevented.

1 is a perspective view schematically showing a microLED display panel according to the present invention;
2 is a cross-sectional view showing the structure of a microLED display panel according to the present invention in detail.
3 is a cross-sectional view showing the structure of the microLED shown in FIG.
4 is a diagram schematically illustrating a tiling microLED display in which a plurality of microLED display panels are tiled;
5 is a plan view showing adjacent display panels of the tiling microLED display device according to the present invention.
6 is a plan view schematically illustrating an assembled microLED display panel in horizontal and vertical directions as a tiling microLED display device according to the present invention.
7A and 7B are diagrams illustrating a method of preventing the generation of dark lines in the horizontal direction in a microLED display device;
8 is a block diagram illustrating a data correction unit of a microLED display device according to the present invention.
9A and 9B are views showing another method of preventing the generation of dark lines in the horizontal direction in a microLED display device;
10A and 10B are diagrams illustrating a method for preventing a dark line in the vertical direction from being generated in a microLED display device;
11A to 11C are diagrams illustrating another method of preventing dark lines in a vertical direction (vertical direction) from being generated in a microLED display device.

Advantages and features of the present invention and methods of achieving them will become apparent with reference to the embodiments described below in detail in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but will be implemented in various different forms, and only these embodiments allow the disclosure of the present invention to be complete, and common knowledge in the technical field to which the present invention belongs It is provided to fully inform the possessor of the scope of the invention, and the present invention is only defined by the scope of the claims.

The shapes, sizes, proportions, angles, numbers, etc. disclosed in the drawings for explaining the embodiments of the present invention are illustrative and the present invention is not limited to the illustrated matters. Like reference numerals refer to like elements throughout. In addition, in describing the present invention, if it is determined that a detailed description of a related known technology may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. When 'including', 'having', 'consisting', etc. mentioned in this specification are used, other parts may be added unless 'only' is used. When a component is expressed in the singular, the case in which the plural is included is included unless specifically stated otherwise.

In interpreting the components, it is interpreted as including an error range even if there is no separate explicit description.

In the case of a description of the positional relationship, for example, when the positional relationship of two parts is described as 'on', 'on', 'on', 'beside', etc., 'right' Alternatively, one or more other parts may be positioned between two parts unless 'directly' is used.

In the case of a description of a temporal relationship, for example, 'immediately' or 'directly' when a temporal relationship is described as 'after', 'following', 'after', 'before', etc. It may include cases that are not continuous unless this is used.

Although the first, second, etc. are used to describe various components, these components are not limited by these terms. These terms are only used to distinguish one component from another. Accordingly, the first component mentioned below may be the second component within the spirit of the present invention.

Each feature of the various embodiments of the present invention may be partially or wholly combined or combined with each other, technically various interlocking and driving are possible, and each of the embodiments may be implemented independently of each other or may be implemented together in a related relationship. may be

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 is a view showing a microLED display panel according to an embodiment of the present invention.

As shown in FIG. 1 , a microLED display panel 100 according to an embodiment of the present invention includes a substrate 110 and a plurality of microLEDs 140 mounted on the substrate 110 .

The substrate 110 may be made of a transparent material such as glass, and a plurality of pixel regions P are formed. Although not shown in the drawings, the substrate 110 is a TFT array substrate, and a thin film transistor and various wirings for driving the microLED 140 are formed in the pixel region P of the upper surface. When the thin film transistor is turned on, a driving signal input from the outside through the wiring is applied to the micro LED 140 so that the micro LED 140 emits light to realize an image.

At this time, since three microLEDs 140R, 140G, and 140B emitting monochromatic light of R, G, and B are mounted in each pixel region P of the substrate 110, R, Lights of R, G, and B colors are emitted from the G and B microLEDs (140R, 140G, 140B) to display an image.

The microLEDs 140R, 140G, and 140B are manufactured by a process separate from the TFT array process of the substrate 110 . In a general organic light emitting display device, both the TFT array process and the organic light emitting layer are formed by a photo process, whereas in the microLED display device of the present invention, the thin film transistors and various wirings disposed on the substrate 110 are formed by a photo process. Although formed, the microLEDs 140R, 140G, and 140B are manufactured by a separate process, and a display device is manufactured by transferring the separately manufactured microLEDs 140R, 140G, and 140B onto the substrate 110 . .

The micro LED 140 is an LED of 10-100 μm in size. After growing a plurality of thin films of inorganic materials such as Al, Ga, N, P, and As In on a sapphire substrate or a silicon substrate, the sapphire substrate or the silicon substrate is cut. It can be formed by separating. As described above, since the microLED 140 is formed in a fine size, it can be transferred to a flexible substrate such as plastic, thereby making it possible to manufacture a flexible display device. In addition, since the microLED 140 is formed by growing an inorganic material as a thin film, unlike the organic light emitting layer, the manufacturing process is simple and the yield is improved. In addition, since the individually separated microLEDs 140 are simply transferred onto the large-area substrate 110, a large-area display device can be manufactured. Moreover, the microLED 140 made of an inorganic material has advantages in that the luminance is high, the lifespan is long, and the unit price is low compared to the LED made of the organic light emitting material.

Although not shown in the drawings, a plurality of gate lines and a plurality of data lines are disposed in vertical and horizontal directions on the substrate 110 to define a plurality of pixel regions P having a matrix shape. In this case, the gate line and the data line are connected to the microLED 140 , and a gate pad and a data pad connected to the outside are provided at the ends of the gate line and the data line, respectively, so that an external signal is transmitted to the gate line and the data line. By being applied to the microLED 140 through the line, the microLED 140 operates and emits light.

2 is a cross-sectional view specifically showing the structure of the microLED display device 100 according to the present invention. At this time, only the outermost sub-pixel of the microLED display device 100 is shown in the drawings for convenience of explanation.

As shown in FIG. 2 , a thin film transistor (TFT) is disposed in the display area of the substrate 110 and a pad 152 is disposed in the pad area. The substrate 110 is made of a transparent material such as glass, but is not limited thereto and may be made of various transparent materials. In addition, the substrate 110 may be made of a flexible transparent material.

The thin film transistor (TFT) includes a gate electrode 101 formed on the substrate 110 , a gate insulating layer 112 formed over the entire area of the substrate 110 to cover the gate electrode 101 , and the gate insulating material. It includes a semiconductor layer 103 formed on the layer 112 , and a source electrode 105 and a drain electrode 107 formed on the semiconductor layer 103 .

The gate electrode 101 may be formed of a metal such as Cr, Mo, Ta, Cu, Ti, Al or an Al alloy or an alloy thereof, and the gate insulating layer 112 is made of an inorganic insulating material such as SiOx or SiNx. It may be made of a single layer made of or a plurality of layers made of SiOx and SiNx.

The semiconductor layer 103 may be made of an amorphous semiconductor such as amorphous silicon, or an oxide semiconductor such as IGZO (Indium Gallium Zinc Oxide), TiO ₂ , ZnO, WO ₃ , SnO ₂ . When the semiconductor layer 103 is formed of an oxide semiconductor, the size of the thin film transistor (TFT) can be reduced, driving power can be reduced, and electric mobility can be improved. Of course, in the present invention, the semiconductor layer of the thin film transistor is not limited to a specific material, and all kinds of semiconductor materials currently used in the thin film transistor may be used.

The source electrode 105 and the drain electrode 107 may be formed of a metal such as Cr, Mo, Ta, Cu, Ti, Al, or an Al alloy or an alloy thereof. At this time, the drain electrode 107 acts as a first electrode for applying a signal to the microLED.

Meanwhile, in the drawings, a thin film transistor (TFT) is a bottom gate type thin film transistor, but the present invention is not limited to a thin film transistor having such a specific structure, but various structures such as a top gate type thin film transistor. A thin film transistor may be applied.

The pad 152 disposed in the pad region may be formed of a metal such as Cr, Mo, Ta, Cu, Ti, Al, or an Al alloy or an alloy thereof. In this case, the pad 152 may be formed by a process different from that of the gate electrode 101 of the thin film transistor (TFT), but for the simplification of the process, the pad 152 is formed in the same process as the gate electrode 101 . it would be preferable

Although not shown in the drawing, the pad may be formed on the gate insulating layer 112 . At this time, the pad may be formed by a process different from that of the source electrode 105 and the drain electrode 107 of the thin film transistor (TFT). ) would be desirable to form in the same process as

In addition, the second electrode 109 is formed on the gate insulating layer 114 of the display area. In this case, the second electrode 109 may be formed of a metal such as Cr, Mo, Ta, Cu, Ti, Al or Al alloy or an alloy thereof, and the second electrode 107 (ie, the drain of the thin film transistor). electrode) and may be formed by the same process.

A first insulating layer 114 is formed on the substrate 110 on which the thin film transistor (TFT) is formed, and the microLED 140 is disposed on the first insulating layer 114 in the display area. At this time, in the drawing, a part of the first insulating layer 114 is removed and the microLED 140 is disposed in the removed region, but the first insulating layer 114 may not be removed. The first insulating layer 114 may be composed of an organic layer such as photoacrylic, may be composed of an inorganic layer/organic layer, or may be composed of an inorganic layer/organic layer/inorganic layer.

The microLED 140 mainly uses a III-V nitride semiconductor material, but is not limited thereto.

3 is a diagram showing the structure of the microLED 140 of the display device according to the present invention. 3, the microLED 140 according to the present invention has an undoped GaN layer 144, an n-type GaN layer 145 disposed on the GaN layer 144, and the n-type GaN layer. An active layer 146 having a Multi-Quantum-Well (MQW) structure disposed on the layer 145, a p-type GaN layer 147 disposed on the active layer 145, and a transparent conductive material. An ohmic contact layer 148 disposed on the p-type GaN layer 147 , a p-type electrode 141 in contact with a portion of the ohmic contact layer 148 , the active layer 146 , and a p-type GaN layer 147 and an n-type electrode 143 in contact with a portion of the n-type GaN layer 145 exposed by etching a portion of the ohmic contact layer 148 .

The n-type GaN layer 145 is a layer for supplying electrons to the active layer 146 and is formed by doping the GaN semiconductor layer with an n-type impurity such as Si.

The active layer 146 is a layer in which injected electrons and holes are combined to emit light. Although not shown in the drawing, in the multi-quantum well structure of the active layer 146, a plurality of barrier layers and well layers are alternately disposed, and the well layer is composed of an InGaN layer and the barrier layer is composed of GaN, but is limited thereto. not.

The p-type GaN layer 147 is a layer for injecting holes into the active layer 146 , and is formed by doping a GaN semiconductor layer with p-type impurities such as Mg, Zn, and Be.

The ohmic contact layer 148 is for ohmic contact between the p-type GaN layer 147 and the p-type electrode 141, ITO (Indium Tin Oxide), IGZO (Indium Galium Zinc Oxide), A transparent metal oxide such as Indium Zinc Oxide (IZO) may be used.

The p-type electrode 141 and the n-type electrode 143 may be formed of a single layer or a plurality of layers made of at least one of Ni, Au, Pt, Ti, Al, and Cr or an alloy thereof. .

In the microLED 140 having this structure, as a voltage is applied to the p-type electrode 141 and the n-type electrode 143, the active layer ( When electrons and holes are respectively injected into the active layer 146, excitons are generated in the active layer 146, and as these excitons decay, the lowest unoccupied molecular orbital (LUMO) and highest occupied molecular orbital (HOMO) of the emission layer ), the light corresponding to the energy difference is generated and emitted to the outside.

At this time, the wavelength of light emitted from the microLED 140 can be controlled by adjusting the thickness of the barrier layer of the multi-quantum well structure of the active layer 146 .

The microLED 140 is formed in a size of about 10-100 μm. Although not shown in the drawings, the microLED 140 is manufactured by forming a buffer layer on a substrate and growing a GaN thin film on the buffer layer. In this case, as a substrate for growing the GaN thin film, sapphire, silicon (si), GaN, silicon carbide (SiC), gallium arsenide (GaAs), zinc oxide (ZnO), or the like may be used.

In addition, the buffer layer prevents quality degradation due to lattice mismatch that occurs when the n-GaN layer 120, which is an epi layer, is directly grown on the substrate when the GaN thin film growth substrate is made of a material other than the GaN substrate. For this purpose, AlN or GaN may be used.

The n-type GaN layer 145 may be formed by growing a GaN layer 144 undoped with impurities and then doping an n-type impurity such as Si on the undoped thin film. In addition, the p-type GaN layer 147 may be formed by growing an undoped GaN thin film and then doping p-type impurities such as Mg, Zn, and Be.

Although the microLED 140 of a specific structure is disposed on the first insulating layer 114 in the drawing, the present invention is not limited to the microLED 140 of this specific structure, such as a vertical microLED and a horizontal microLED. MicroLEDs of various structures can be applied.

Referring again to FIG. 2 , a second insulating layer 116 is formed on the first insulating layer 114 on which the microLED 140 is mounted. At this time, the second insulating layer 116 may be composed of an organic layer such as photoacrylic, may be composed of an inorganic layer/organic layer, may be composed of an inorganic layer/organic layer/inorganic layer, cover the upper area.

A first contact hole 114a and a second contact hole 114b are formed in the first insulating layer 114 and the second insulating layer 116 on the thin film transistor TFT and the second electrode 119, respectively. The drain electrode 107 and the second electrode 119 of the thin film transistor TFT are exposed to the outside, respectively. In addition, a third contact hole 116a and a fourth contact hole 116b are formed in the second insulating layer 116 on the p-type electrode 141 and the n-type electrode 143 of the microLED 140, respectively. This is formed to expose the p-type electrode 141 and the n-type electrode 143 to the outside.

A first connection electrode 117a and a second connection electrode 117b made of a transparent metal oxide such as ITO, IGZO, or IGO are formed on the second insulating layer 116 to form the first contact hole 114a and the drain electrode 107 of the thin film transistor (TFT) and the p-type electrode 141 of the microLED 140 are electrically connected by the first connection electrode 117a through the third contact hole 116a. , the second electrode 109 and the n-type electrode 143 of the microLED 140 are electrically connected through the second contact hole 114b and the fourth contact hole 116b by the second connection electrode 117b. is connected to

On the other hand, link lines 154 are formed on the upper surface, the side surface, and the rear surface of the substrate 110 in the pad area. In addition, the signal module 170 is disposed on the rear surface of the substrate 110 , and is electrically connected to the pad 152 on the upper surface of the substrate 110 through the link line 154 .

The signal module 170 includes a circuit such as a timing controller, a memory such as an EEPROM, a voltage source for driving the microLED 140, and various wirings electrically connected to the link line 154 (Printed Circuit Board) It may also be a PCB in which a gate driver and a data driver for applying a scan signal and an image signal to the gate line and the data line, respectively, are formed.

In this structure, after the signal output from the signal module 170 is applied to the pad 152 through the link line 154, the signal is supplied through the gate line and the data line to turn on the thin film transistor TFT. As the thin film transistor (TFT) is turned on, a signal is supplied to the microLED 140 through the thin film transistor (TFT) and the second electrode 109 so that the microLED 140 emits light.

Meanwhile, the link line 154 is formed on the upper surface, the side surface, and the rear surface of the substrate 110 to electrically connect the pad 152 and the signal module 170 .

In addition, a buffer layer 118 made of an inorganic material and/or an organic material is formed on a portion of the upper surface, the side surface, and the rear surface of the substrate 110 to cover the microLED 140 and the link line 154 .

As described above, in the present invention, since the link line 154 is formed from the top surface of the substrate 110 through the side surface to the rear surface and is connected to the signal module 170, the bezel area of the display device can be minimized.

In the case of a conventional organic light emitting display device, a flexible printed circuit board (FPCB) having various wirings formed thereon was attached to the pad area, and then the FPCB was folded to the rear side and connected to the signal module on the rear side. Therefore, in the case of a conventional organic light emitting display device, an area to which the FPCB is adhered is required, which increases the area of the pad area, and a space for folding the FPCB rearward is required. must do it.

However, in the microLED display device of the present invention, the link line 154 is disposed on the side of the substrate 110 without the FPCB, so that the pad 152 on the upper surface of the substrate 110 and the signal module 170 on the rear of the substrate 110 are connected. Since it is connected, the attachment area and folding space of the FPCB are not required, and the bezel can be greatly reduced.

4 is a view showing a microLED display device according to the present invention. The microLED display device of this embodiment is a display device in which a plurality of microLED display panels 100 of the structure shown in FIG. 1 are tiled. In the drawings, four microLED display panels 100 are tiled for convenience of description, but six, eight, or more microLED display panels 100 may be tiled to form a microLED display device. .

As shown in FIG. 4 , the tiling microLED display device according to the present invention is configured by tiling a plurality of microLED display panels 100 . Each of the microLED display panels 100 includes a plurality of pixel regions P, and a first microLED 140 and a second microLED 142 are disposed in each pixel region P. The first microLED 140 is composed of R,G,B microLEDs 140R, 140G, and 140B, and the second microLED 142 is also composed of R,G,B microLEDs 142R, 142G, and 142B. is composed

The first microLED 140 is a main light emitting microLED that emits light according to an image signal applied from the outside to implement an image, and the second microLED 142 is a redundancy microLED and is a first microLED of a specific pixel. When a defect occurs in the LED 140 , it may operate instead of the first micro LED 140 . Although not shown in the drawings, gate lines, data lines, and thin film transistors for implementing the first microLED 140 are formed in the pixel region of each microLED display panel 100 as well as the second microLED 142 . A redundancy gate line, a redundancy data line, and a redundancy thin film transistor are formed for driving. In other words, the first microLED 140 and the second microLED 142 operate separately by different thin film transistors.

The first microLED 140 and the second microLED 142 are formed in the same structure and have the same light emitting characteristics. At this time, the first microLED 140 and the second microLED 142 have the structure shown in FIG. 3 , and the first microLED 140 and the second microLED are formed on the structure shown in FIG. 2 . By transferring 142, a microLED display is fabricated.

5 is a plan view showing two microLED display panels 100 adjacent to each other of the tiling microLED display according to the present invention. In addition, for convenience of explanation, only the pixel area formed in the outermost area of the pixel area P of each microLED display panel 100 and adjacent to the other microLED display panel 100 is shown in the drawings.

As shown in FIG. 5 , two microLED display panels 100 adjacent to each other are tiled with a set interval d. In addition, the first microLED 140 and the second microLED 142 are respectively disposed on the microLED display panel 100 .

Although not shown in the drawings, a plate to which the plurality of micro LED display panels 100 are fastened is provided on the rear surface of the plurality of micro LED display panels 100 . At this time, the fastening of the microLED display panel 100 to the plate may be performed by various methods. For example, the microLED display panel 100 can be fastened to the plate by screwing the microLED display panel 100 to the plate with a tool, and a separate fastening mechanism is provided for each of the plate and the microLED display panel 100 . may be formed to fasten the microLED display panel 100 to the plate.

At this time, the three R, G, and B first microLEDs 140R, 140G, and 140B are arranged in a row along the horizontal direction (x-direction) in the pixel area of the microLED display panel 100 , and the three R ,G,B The second microLEDs 142R, 142G, and 142B are also arranged in a row along the horizontal direction (x-direction) in the pixel area.

The plurality of microLED display panels 100 are tiled at a predetermined interval d.

On the other hand, in order to manufacture the tiling microLED display device as described above, the steps of forming TFTs and various wirings on the substrate, transferring the microLEDs onto the substrate on which the TFTs and various wirings are formed, and the side of the microLED display panel 100 A step of forming a link line on the pole, attaching the microLED display panel 100 to a plate, and tiling a plurality of microLED display panels 100 should be performed.

In this process, a tolerance is required to smoothly manufacture a tiling microLED display device, and due to this tolerance, the actual spacing d of two adjacent microLED display panels 100 exceeds or less than the tolerance t. This will happen to happen.

For example, a gap d between adjacent microLED display panels 100 occurs, but if this gap d is within the allowable tolerance t, the gap between adjacent microLED display panels 100 is not recognized by the user. However, when the gap d between the adjacent microLED display panels 100 exceeds the void tolerance t, the gap between the adjacent microLED display panels 100 is tiled by a seam recognized by the user. It appears on the screen of the microLED display.

As such, in the tiling microLED display device, if the interval (d) between the adjacent microLED display panels 100 exceeds the allowable tolerance (t), a defect in which the dark wire seam is displayed on the screen of the tiling microLED display device will occur

In order not to exceed the error range as described above, it is necessary to tightly manage the tolerance range of each process when manufacturing the tiling microLED display device.

In the present invention, by arranging the second microLED 142 in the pixel region P of the microLED display panel 100, it is possible to prevent the core from being displayed on the screen. That is, in the present invention, not only the second microLED 142, which is a redundancy LED, is driven only when the first microLED 140 is defective, but the interval d between adjacent microLED display panels 100 has a tolerance ( t) is exceeded to prevent the shim from being displayed on the screen.

Hereinafter, a method for preventing the display of the seam on the screen by the second microLED 142 according to the present invention will be described.

6 is a plan view schematically illustrating an assembled microLED display panel 100 in horizontal and vertical directions as a tiling microLED display device according to the present invention. At this time, although the microLED display panel 100 includes a plurality of pixel regions, only the pixel regions of regions adjacent in the horizontal and vertical directions are shown in the drawings for convenience of explanation.

As shown in FIG. 6 , in the tiling microLED display device according to the present invention, a plurality of microLED display panels 100 are tiled in a horizontal direction (x-direction) and a vertical direction (y-direction). In this case, the microLED display panel 100 is arranged at intervals of d1 in the vertical direction and at intervals of d2 in the horizontal direction.

A first microLED 140 and a second microLED 142 that emit light as a signal is applied are disposed in each microLED display panel 100 . The first microLED 140 includes R, G, and B microLEDs 140R, 140G, and 140B emitting R, G, and B colors, and the second micro LED 142 includes R, G, and B colors. Includes R, G, B microLEDs 142R, 142G, and 140B that emit light.

At this time, the first microLED 140 and the second microLED 142 are arranged to be spaced apart from each other by a set distance (s) in the vertical direction. In this case, the vertical movement distance between the first microLED 140 and the second microLED 142 may vary depending on the resolution of the microLED display panel 100 , that is, the size of the pixel area.

It is most ideal that the intervals d1 and d2 of the microLED display panels 100 adjacent to each other are 0. That is, when there is no gap between the microLED display panels 100 to be tiled, the image of the microLED display panel 100 and the image of the boundary region of the microLED display panel 100 are the same on the screen of the actual microLED display device. As a result, no seam is displayed on the screen.

When the distance (d1, d2) between the microLED display panels 100 is increased, the luminance of the area between the microLED display panels 100 is decreased and displayed as dark lines on the screen.

Even if these dark lines are displayed on the screen, if the luminance is higher than the set luminance, the human cannot recognize them. In other words, if the interval between the microLED display panels 100 does not exceed the set range (ie, allowable tolerance), it is determined that the shim is not displayed on the screen because the human cannot recognize it.

When the interval between the microLED display panels 100 increases and the interval exceeds the allowable tolerance, a dark line is displayed on the screen and the user can recognize it. Such dark lines can be removed by adjusting the intensity of voltage or current applied to the microLEDs 140 and 142 by data compensation. That is, by adjusting the luminance of the microLEDs 140 and 142 adjacent to the boundary region between the microLED display panel 100 on which the dark lines are displayed, the dark lines can be removed.

However, since there is a limit to the luminance compensation in the boundary region between the microLED display panels 100, the interval (d1, d2) between the adjacent microLED display panels 100 is further increased to increase the set value (α: data compensation). If it exceeds the value at which dark lines can be removed), dark lines are generated on the screen despite data compensation.

In the present invention, when the interval (d1, d2) between the adjacent microLED display panels 100 exceeds a set value, by controlling the driving of the first microLED 140 and the second microLED 142, the Prevents cancerous glands from forming in

7A and 7B are diagrams illustrating a method of preventing dark lines from being generated in a horizontal direction (horizontal direction) in a microLED display device. In the drawings, only two pixel areas P are shown along the boundary area of the microLED display panel adjacent to each other for convenience of explanation.

As shown in FIG. 7A , the first microLED display panel 100a and the second microLED display panel 100b each including a plurality of pixel areas P11, P12, P21, and P22 are aligned in the vertical direction (y- direction), the first microLED 140 includes R, G, and B microLEDs 140R, 140G, and 140B arranged in a horizontal direction, and the second microLED 142 is also arranged in a horizontal direction. ,G,B Includes microLEDs 142R, 142G, and 142B.

When the distance d1 between the first microLED display panel 100a and the second microLED display panel 100b is smaller than the allowable tolerance t (d1<t), the first microLED display panel 100a and In each of the pixel areas P11, P12, P21, and P22 of the second microLED display panel 100b, the first microLED 140 emits light to display an image. do not recognize

As shown in FIG. 7B , when the gap d1 between the first microLED display panel 100a and the second microLED display panel 100b increases, the first microLED display panel 100a and the second In the boundary region between the microLED display panels 100b, the luminance is lowered and dark lines are generated.

When the distance (d) between the first microLED display panel 100a and the second microLED display panel 100b is larger than the allowable tolerance (t) (d>t), the data is compensated by photographing the displayed screen By adjusting the voltage or current applied to the currently emitting first microLED 140 to adjust the luminance of the first microLED 140, dark lines are removed.

When the interval d1 between the first microLED display panel 100a and the second microLED display panel 100b is greater than the set value α (d1>α), the data of the first microLED 140 Since the dark line is not removed by the correction, the second microLED 142 that does not emit light among the microLEDs in the pixel area adjacent to the boundary between the microLED display panels 100a and 100b is additionally driven. In particular, dark lines in the boundary area are removed by additionally driving the second microLEDs 142 disposed in the pixel areas P11 and P12 of the first microLED display panel 100a closest to the boundary.

In other words, the first microLED 140 and the second microLED ( 142), and only the first microLED 140 is driven in the pixel regions P21 and P22 of the second microLED display panel 100b.

As described above, in the present invention, the second microLED 142, which is the redundancy microLED closest to the region where the dark line is generated, is additionally driven so that the light emitted from the second microLED 142 is output to the dark line region. By doing so, the dark wire can be removed.

On the other hand, if the luminance of the additionally driven second microLED 142 is too low, the dark lines remain without being completely removed. If the luminance of the additionally driven second microLED 142 is too high, the dark lines are removed but the bright lines are removed. It can be marked again with this shim. In addition, since the width and luminance of the dark line vary according to the distance d1 between the first microLED display panel 100a and the second microLED display panel 100b, in the additionally driven second microLED 142 When light of the same luminance is always emitted, dark lines may be removed depending on the distance d1 and luminance between the first microLED display panel 100a and the second microLED display panel 100b, but the dark lines remain or rather bright lines. This may happen.

Accordingly, in order to further drive the second microLED 142 so that a seam is not displayed between the adjacent microLED display panels 100a and 100b, the signal applied to the second microLED 142 according to data compensation is applied. It is necessary to adjust the luminance and color of the second microLED 142 by adjusting.

Compensation of such data is made by a data correction unit provided in a circuit module disposed on the rear surface of the microLED display panel.

8 is a view showing the data correction unit 200 of the microLED display device according to the present invention.

As shown in FIG. 8 , the data correction unit 200 includes a compensation value generator 210 , a data modulator 220 , and a filter unit 230 .

The compensation value generator 210 is configured to generate a compensation value for each pixel area based on image data input from an imaging device such as a CCD camera that captures a screen of a display device in which a plurality of microLED display panels 100a and 100b are tiled. create

Although the photographing equipment may photograph the entire screen of the microLED display device, the present invention corrects the data to remove the seam in the area between the tiled microLED display panels 100a and 100b, so the microLED display panels 100a and 100b) Only the boundary area between them can be photographed.

The compensation value generator 210 may compare the input image data with the stored image data to calculate a difference value, and then generate a compensation value based on the difference value. At this time, the compensation value generator 210 creates and stores the generated compensation value as a lookup table. In this case, the compensation value includes compensation values for luminance and color.

The compensation value generating unit 210 includes two adjacent pixel columns centered on a boundary region between the microLED display panels 100a and 100b (ie, the closest pixels of each of the adjacent microLED display panels 100a and 100b). column) as a block, and the pixel columns of 4 adjacent columns with the boundary between the microLED display panels 100a and 100b as the center (that is, the adjacent two adjacent microLED display panels 100a and 100b, respectively) pixel columns) as a block. The setting of the block for generating the compensation value may be determined according to various variables such as the width or intensity of the dark or bright line, the resolution of the display device, the size of the pixel area, and the like.

The data modulator 220 modulates image data input from an external system according to a correction value stored in the lookup table.

In addition, the filter unit 230 filters the image data modulated and input from the data modulator 220 to smooth the image in the compensated area to prevent abrupt change in luminance and color in this area. prevent. A low pass filter may be used as the filter unit 230 .

The image data corrected by the data correction unit 200 is supplied to a timing controller provided in the circuit module 170 . The timing controller generates a data control signal and a gate control signal using a horizontal synchronization signal, a vertical synchronization signal, and a clock signal input from an external system, and supplies the data control signal and the corrected image data to a data driver and performs gate control A signal is supplied to the gate driver.

The data driver samples the corrected image data according to the data control signal input from the timing controller, and then latches the sampled image data corresponding to one horizontal line every number of purchases and supplies the latched image data to the data line. Thus, by driving the second microLED 142, the dark line between the adjacent microLED display panels 100a and 100b can be removed.

As such, in the present invention, when a dark line occurs between adjacent microLED display panels 100a and 100b, by driving the second microLED 142 in the boundary region (not driven in a normal case) arranged for redundancy. , it is possible to prevent the generation of dark lines between the micro LED display panels 100a and 100b. Furthermore, in the present invention, since the luminance and color of the second microLED 142 driven adjacent to the boundary region is corrected by data correction, the user cannot recognize the boundary region between the microLED display panels 100a and 100b at all. there will be no

9A and 9B are views illustrating a method for preventing the generation of dark lines in the horizontal direction (horizontal direction) in a microLED display device. In particular, 1R, G,B microLEDs 140R, 140G, 140B and 2R How to prevent dark lines from occurring when ,G,B microLEDs (142R, 142G, 142B) are arranged in two rows in the pixel area and the microLEDs operate in a delta (Δ) shape or inverse delta (▽) shape It is a drawing showing

As shown in FIG. 9A , the first microLED display panel 100a and the second microLED display panel 100b each including a plurality of pixel regions P11, P12, P21 and P22 are aligned in the vertical direction (y- direction), and in each of the pixel areas P11, P12, P21, and P22, the first microLED 140 and the second microLED 142 spaced apart from each other by a predetermined distance in the vertical direction are disposed, The LED 140 includes R, G, B microLEDs 140R, 140G, and 140B arranged in a horizontal direction, and the second microLED 142 is a R, G, B microLED 142R, arranged in a horizontal direction. 142G, 142B).

When the distance d between the first microLED display panel 100a and the second microLED display panel 100b is smaller than the allowable tolerance t (d<t), the first microLED display panel 100a and The first microLED 140 and the second microLED 142 emit light in each of the pixel areas P11, P12, P21, and P22 of the second microLED display panel 100b to display an image. It is not displayed or cannot be recognized by the user.

At this time, in one pixel area (P12, P22), the first microLED 140G of G color is driven and the second microLEDs 142R, 142B of color R and B are driven to emit light R, G, B Colored microLEDs are arranged in a delta (Δ) shape to realize an image. In addition, in the pixel areas P11 and P21 adjacent to the pixel area P in the vertical direction, the first microLEDs 140R and 140B of R and B colors are driven and the second microLEDs 142G of the G color are driven. MicroLEDs of R, G, and B colors that emit light by driving are arranged in an inverse delta (▽) shape to realize an image.

The pixel areas in which the emitting R, G, and B color microLEDs are arranged in a delta (Δ) shape and an inverse delta (▽) shape are alternately arranged in the horizontal direction, that is, along the gate line direction, so that the image is displayed on the entire microLED display device. to display In addition, in the vertical direction or the data line direction, a pixel region in which R, G, and B color microLEDs emitting light are arranged in a delta (Δ) shape or an inverse delta (?) shape is arranged. However, pixel regions in which microLEDs emitting light in the vertical direction are arranged in a delta (Δ) shape and in an inverse delta (?) shape may be alternately arranged.

As shown in FIG. 9B , when the interval d1 between the first microLED display panel 100a and the second microLED display panel 100b increases and becomes larger than the allowable tolerance t (d1>t), the second In the boundary region between the 1 micro LED display panel 100a and the second micro LED display panel 100b, the luminance is lowered and dark lines are generated.

When the interval d1 between the first microLED display panel 100a and the second microLED display panel 100b is smaller than the set value α (d1<α), the data is compensated by photographing the displayed screen. By adjusting the luminance of the microLEDs 140 and 142 by adjusting the voltage or current applied to the currently emitting microLEDs 140 and 142, dark lines are removed.

When the interval d1 between the first microLED display panel 100a and the second microLED display panel 100b is greater than the set value α (d1>α), it is necessary to adjust the brightness of the currently emitted microLED. Since the dark line is not removed by using the method, a part of the microLEDs 140 and 142 that do not emit light in the pixel areas P11, P12, P21, and P22 adjacent to the boundary area are additionally driven to remove the dark line.

That is, the first microLED (140G) of G color and the second microLED (142R, 142B) of R, B color are driven and the R, G, and B color microLEDs emit light in a delta (Δ) shape. In the second pixel region P12 of the first microLED display panel 100a, a second microLED 142G of G color is additionally driven, and a second microLED display panel 100b that is vertically adjacent to each other with a boundary therebetween. ), the first microLEDs 140R and 140G of R and B colors are additionally driven in the second pixel region P22. Accordingly, the G-color micro LED 140G emits light in the second pixel region P12 of the first microLED display panel 100a adjacent to each other and the second pixel region P22 of the second microLED display panel 100b. ), the R, B color microLEDs 142R, 142B emit light, and one delta (Δ)-shaped R, G, B microLED is added over two vertically adjacent pixel areas P12 and P22. will drive

In addition, it is also possible to additionally drive delta (Δ)-shaped R, G, and B microLEDs across four or more vertically adjacent pixel areas. In this case, two or more delta (Δ)-shaped R, G, and B microLEDs may be additionally driven in four or more vertically adjacent pixel areas.

Accordingly, the pixel regions P12 and P22 of the first microLED display panel 100a and the second microLED display panel 100b in which the microLEDs of R, G, and B colors emit light in a delta (Δ) shape around the boundary. ), a delta (Δ)-shaped microLED is additionally driven to remove dark lines in the boundary area.

In addition, the first pixel region P11 and the second microLED display panel of the first microLED display panel 100a in which the microLEDs of R, G, and B colors emit light in an inverse delta (▽) shape around the boundary region. For the first pixel region P21 of (100b), one inverse delta (▽) microLED is additionally driven over the two pixel regions P11 and P21, or one over the four or more pixel regions The above inverse delta (▽) shape microLED is additionally driven to remove dark lines in the boundary area.

As described above, in the present invention, the dark line can be removed by the light emitted from the additionally driven microLED by additionally driving the non-operating microLED in the region where the dark line is generated.

At this time, the additionally driven microLED emits light by applying a signal compensated by the data correction unit as shown in FIG. 8 .

10A and 10B are diagrams illustrating a method of preventing dark lines from being generated in a vertical direction (vertical direction) in a microLED display device.

As shown in FIG. 10A , the first microLED display panel 100a and the second microLED display panel 100b each including a plurality of pixel regions P are adjacent in the horizontal direction (x-direction), In each of the pixel areas P11, P12, P21, and P22, the first microLED 140 and the second microLED 142 spaced apart from each other by a predetermined distance in the vertical direction are disposed, and the first microLED 140 is horizontally spaced apart from each other. R, G, B microLEDs (140R, 140G, 140B) arranged in a line in the direction, and the second microLED 142 is arranged in a row in the horizontal direction R, G, B microLEDs (142R, 142G, 142B).

When the distance d between the first microLED display panel 100a and the second microLED display panel 100b is smaller than the allowable tolerance t (d<t), the first microLED display panel 100a and In each of the pixel areas P11, P12, P21, and P22 of the second microLED display panel 100b, the first microLED 140 emits light to display an image.

As shown in FIG. 10B , when the gap d2 between the first microLED display panel 100a and the second microLED display panel 100b becomes larger than the allowable tolerance t (d2>t), the first microLED display panel 100b In the boundary region between the LED display panel 100a and the second microLED display panel 100b, the luminance is lowered and dark lines are generated.

When the interval d2 between the first microLED display panel 100a and the second microLED display panel 100b is smaller than the set value α (d2<α), the data is compensated by photographing the displayed screen. By adjusting the luminance of the microLEDs 140 and 142 by adjusting the voltage or current applied to the currently emitting microLEDs 140 and 142, dark lines are removed.

When the distance d2 between the first microLED display panel 100a and the second microLED display panel 100b is greater than the set value α (d2>α), the luminance of the first microLED 140 is Since the dark line is not removed by the adjustment, a part of the microLEDs 140 and 142 that do not emit light in the pixel areas P11, P12, P21, and P22 adjacent to the boundary are additionally driven to remove the dark line.

That is, the second microLED 142B of the B color in the first pixel region P11 of the first microLED display panel 100a is further driven and the first pixel of the adjacent second microLED display panel 100b is driven. By additionally driving the second microLEDs 142R and 142G of the R and G colors in the region P21, 2 adjacent to the boundary between the first microLED display panel 100a and the second microLED 142R as the center One R, G, and B microLED emits light across the pixel areas P11 and P21 to remove dark lines in the boundary area.

In addition, the second microLEDs 142G and 142B of G and B colors in the second pixel region P12 of the first microLED display panel 100a vertically adjacent to the first pixel regions P11 and P21 are formed. Further driving and driving the second microLED 142R of the R color in the second pixel region P22 of the second microLED display panel 100b further drives the first microLED display panel 100a and the second One R, G, and B microLED emits light over the two adjacent pixel areas P12 and P22 around the boundary of the microLED 142R, thereby removing dark lines in the boundary area.

At this time, the R, G, and B microLEDs that additionally emit light in the two pixel regions P11 and P21 are arranged in R, G, and B, and R, which additionally emits light in the two adjacent pixel regions P12 and P22; Since the G,B microLEDs are arranged in G,B,R, it is possible to remove dark lines and improve the visibility of images in this area at the same time.

However, the R, G, and B microLEDs that additionally emit light in the two pixel regions may all be arranged in R, G, B or G, B, R. That is, in the present invention, the additionally emitting R, G, and B microLEDs may be arranged in various orders, not in a specific order.

Meanwhile, the additionally driven microLED emits light by applying a signal compensated by the data correction unit as shown in FIG. 8 .

11A to 11C are views illustrating a method for preventing dark lines in the vertical direction (vertical direction) from being generated in a microLED display device. In particular, R, G, and B microLEDs are arranged in two rows in the pixel area and the delta (Δ) ) shape or inverse delta (▽) shape is a diagram showing a method of preventing dark lines from occurring when the microLED is operated.

As shown in FIG. 11A , the first microLED display panel 100a and the second microLED display panel 100b each including a plurality of pixel regions P11, P12, P21, and P22 move in the horizontal direction (x- direction), and in each pixel area P, the first microLED 140 and the second microLED 142 spaced apart from each other by a predetermined distance in the vertical direction are disposed, and the first microLED 140 is horizontally spaced apart from each other. R, G, B microLEDs (140R, 140G, 140B) arranged in the direction and the second microLED 142 includes R, G, B microLEDs (142R, 142G, 142B) arranged in the horizontal direction do.

When the distance d between the first microLED display panel 100a and the second microLED display panel 100b is smaller than the allowable tolerance t (d<t), the first microLED display panel 100a and In each of the pixel areas P11, P12, P21, and P22 of the second microLED display panel 100b, the first microLED 140 and the second microLED 142 emit light to display an image.

At this time, in the first and second pixel regions P11 and P12 of the first microLED display panel 100a, the first microLED 140G of G color is driven, respectively, and the second macroLED of R and B color ( 142R, 142B), emitting R, G, and B color microLEDs are arranged in a delta (Δ) shape to realize an image. In addition, in the first and second pixel regions P21 and P22 of the second microLED display panel 100b that are horizontally adjacent to the first microLED display panel 100a and a predetermined distance d2 in the horizontal direction, R color and The first microLEDs of B color (140R, 140B) are driven and the second microLEDs of G color (142G) are driven, and the R, G, and B color microLEDs that emit light are arranged in an inverse delta (▽) shape. implement the image.

The pixel areas in which the emitting R, G, and B color microLEDs are arranged in a delta (Δ) shape and an inverse delta (▽) shape are alternately arranged in the horizontal direction, that is, along the gate line direction, so that the image is displayed on the entire microLED display device. to display In addition, a pixel area in which R, G, and B color microLEDs emitting light are arranged in a delta (Δ) shape or an inverse delta (?) shape is disposed in the vertical direction or along the data line direction. However, pixel regions in which the microLEDs are arranged in a delta (Δ) shape and in an inverse delta (▽) shape may be alternately arranged along the vertical direction.

As shown in FIG. 11B , when the distance d2 between the first microLED display panel 100a and the second microLED display panel 100b becomes larger than the allowable tolerance t (d2>t), the first microLED display panel 100b In the boundary region between the LED display panel 100a and the second microLED display panel 100b, the luminance is lowered and dark lines are generated.

When the interval d2 between the first microLED display panel 100a and the second microLED display panel 100b is smaller than the set value α (d2<α), the data is compensated by photographing the displayed screen. By adjusting the luminance of the microLEDs 140 and 142 by adjusting the voltage or current applied to the currently emitting microLEDs 140 and 142, dark lines are removed.

When the distance d2 between the first microLED display panel 100a and the second microLED display panel 100b is greater than the set value α (d2>α), the luminance of the first microLED 140 is Since the dark line is not removed by the adjustment, a part of the microLEDs 140 and 142 that do not emit light in the pixel areas P11, P12, P21, and P22 adjacent to the boundary are additionally driven to remove the dark line.

That is, in the first pixel region P11 of the first microLED display panel 100a in which the emitting R, G, and B color microLEDs emit light in a delta (Δ) shape, the first microLED 140B of the B color of the second microLED display panel 100b adjacent to the first microLED display panel 100a and in which the microLEDs of R, G, and B colors emit light in an inverse delta (▽) shape. A second microLED 142R of R color is additionally driven in the pixel region P21.

In addition, in the second pixel region P12 of the first microLED display panel 100a, the B-color first microLED 140B is additionally driven and the second pixel region (P12) of the second microLED display panel 100b P22) also drives the second microLED (142R) of R color additionally.

As described above, in the present invention, the first microLED 140B of B color in the two pixel regions P11 and P12 adjacent to the boundary region and the second microLED 140B of the R color in the two pixel regions P21 and P22 adjacent to the boundary region ( 142R) is additionally driven, so that dark lines can be removed by the light emitted from the additionally driven microLED.

At this time, the additionally driven microLED emits light by applying a signal compensated by the data correction unit as shown in FIG. 8 .

11c is another method of preventing the occurrence of dark lines in the vertical direction when the R, G, and B microLEDs are arranged in two rows in the pixel area and the microLEDs are operated in a delta (Δ) shape or in an inverse delta (▽) shape. It is a drawing showing

As shown in FIG. 11C , when the interval d2 between the first microLED display panel 100a and the second microLED display panel 100b is greater than the set value α (d2>α), the second Since dark lines are not removed by adjusting the luminance of the 1 microLED 140, some of the microLEDs 140 and 142 that do not emit light in the pixel area adjacent to the boundary are additionally driven to remove the dark lines.

That is, in the first pixel region P11 of the first microLED display panel 100a in which R, G, and B color microLEDs emit light in a delta (Δ) shape, the B color first microLED 140B and G A second microLED display panel in which a color second microLED (142G) is additionally driven, and the microLEDs of R, G, and B colors emit light in an inverse delta (▽) shape by driving adjacent to each other in the horizontal direction with a boundary In the first pixel region P21 of (100b), the R color second microLED 142R is additionally driven.

Therefore, the first pixel region P11 of the first microLED display panel 100a and the first pixel region P21 of the second microLED display panel 100b that are adjacent to each other with a boundary are the additionally driven microLEDs. Light is emitted in one delta (Δ) shape across the two pixel areas P11 and P21, so that dark lines in the boundary area can be removed.

In addition, it is also possible to additionally drive delta (Δ)-shaped R, G, and B microLEDs across four or more pixel areas. In this case, two or more delta (Δ)-shaped R, G, and B microLEDs may be additionally driven in four or more adjacent pixel regions.

In addition, in the second pixel region P12 of the first microLED display panel 100a in which R, G, and B color microLEDs emit light in a delta (Δ) shape, a B color first microLED 140B is added. In the second pixel region P22 of the second microLED display panel 100b driven by A first microLED (140G) of color and a second microLED (142R) of color R are additionally driven.

Accordingly, the second pixel region P12 of the first microLED display panel 100a and the second pixel region P22 of the second microLED display panel 100b that are adjacent to each other with a boundary are the additionally driven microLEDs. One inverse delta (▽) shape is emitted over two pixel areas (P12, P22), or one or more inverse delta (▽) microLEDs are additionally emitted over four or more pixel areas, so that dark lines in the boundary area are emitted. can be removed.

At this time, the additionally driven microLED emits light by applying a signal compensated by the data correction unit as shown in FIG. 8 .

In this method, since the microLEDs in the pixel area adjacent to the boundary area of the adjacent microLED display panels 100a and 100b are additionally driven in the delta (Δ) shape and in the inverse delta (▽) shape, dark lines can be removed as well as In addition, the visibility of the boundary area is also improved.

As described above, in the present invention, a redundancy microLED vertically spaced apart from the main light-emitting microLED by a predetermined distance is provided, and when a dark line occurs due to a tiling error of an adjacent microLED display panel, the main light-emitting microLED and/or redundancy By controlling the driving of the microLED, it is possible to prevent the shim from being displayed on the screen.

The present application described above is not limited to the above-described embodiments and the accompanying drawings, and it is common in the technical field to which this application pertains that various substitutions, modifications, and changes are possible without departing from the technical matters of the present application. It will be clear to those who have the knowledge of Therefore, the scope of the present application is indicated by the following claims, and all changes or modifications derived from the meaning and scope of the claims and their equivalent concepts should be construed as being included in the scope of the present application.

100: micro LED display panel 110: substrate
118: buffer layer 140, 142: micro LED
154: link line 170: circuit module

Claims (17)

a plurality of display panels each including a plurality of pixel areas and tiled at a predetermined tiling interval;
first R, G, and B microLEDs disposed in each pixel area of the display panel to output light of R, G, and B colors; and
It is disposed in each pixel area of the display panel to output light of R, G, and B colors, and consists of second R, G, and B microLEDs vertically spaced apart from the first R, G, and B microLEDs;
An image is realized by driving a main light emitting microLED among the first R, G, and B microLEDs and the second R, G, and B microLEDs, and when the distance between a plurality of tiled display panels exceeds a set value, A microLED display device that additionally drives auxiliary light emitting microLEDs among the first R,G,B microLEDs and the secondR,G,B microLEDs in the pixel area. The microLED display device according to claim 1, wherein the first R,G,B microLED and the secondR,G,B microLED have a size of 10-100 μm. The microLED display device according to claim 1, wherein the main light emitting microLEDs are first R,G,B microLEDs arranged in a line. The microLED display device according to claim 3, wherein the sub-emission microLEDs in the pixel area adjacent to the boundary area between the vertically spaced microLED display panels are the second R,G,B microLEDs. The sub-emission microLED in the pixel region adjacent to the boundary region between the horizontally spaced microLED display panels is two pixel regions among the second R, G, and B micro LEDs in the two pixel regions adjacent to each other. A micro LED display device that is additionally driven in a single R, G, B array. The microLED display device according to claim 1, wherein the main light emitting microLEDs are microLEDs arranged in a delta (Δ) shape among the first R,G,B microLEDs and the secondR,G,B microLEDs arranged in a line. The sub-emission microLEDs in the pixel region adjacent to the boundary region between the vertically spaced microLED display panels are the first R, G, B microLEDs and the second R, G in two adjacent pixel regions. ,B A microLED display device that is a microLED that is additionally driven in a delta (Δ) shape in two pixel areas among microLEDs. The sub-emission microLED in the pixel region adjacent to the boundary region between the horizontally spaced microLED display panels is one of the first R, G, and B microLEDs in the pixel region and the adjacent pixel. A micro LED display device that is one micro LED among the second R, G, and B micro LEDs in the area. According to claim 6, wherein the sub-emission microLEDs in the pixel region adjacent to the boundary region between the horizontally spaced apart microLED display panel includes the first R, G, and B microLEDs in the corresponding pixel region and the second R in the pixel region adjacent to each other; A micro LED display device that is additionally driven in one delta (Δ) shape or inverse delta (▽) shape in two pixel areas among G and B micro LEDs. The microLED display device according to claim 1, wherein the main light emitting microLEDs are microLEDs arranged in an inverse delta (▽) shape among the first R,G,B microLEDs and the secondR,G,B microLEDs arranged in a line. . 11. The method of claim 10, wherein the sub-emission microLEDs in the pixel area adjacent to the boundary area between the vertically spaced microLED display panels are the first R, G, B microLEDs and the second R, G in two adjacent pixel areas. ,B Micro LED display device, which is a micro LED that is additionally driven in an inverse delta (▽) shape in two pixel areas among micro LEDs. The method of claim 1, wherein the display panel comprises:
Board;
a gate line and a data line disposed on the upper surface of the substrate;
a thin film transistor disposed on the upper surface of the substrate; and
A microLED display device including a circuit module disposed on a rear surface of a substrate. The microLED display device according to claim 1, further comprising a data correction unit for correcting the color and luminance of the auxiliary light emitting microLED. 14. The method of claim 13, wherein the data correction unit
a compensation value generator for generating a compensation value based on the image data of the captured screen; and
A microLED display device comprising a data modulator for modulating image data input from an external system according to the generated compensation value. 15. The microLED display device of claim 14, wherein the compensation value generator creates and stores the generated compensation value as a lookup table. 15. The microLED display device of claim 14, wherein the data correction unit further comprises a filter unit for filtering the input image data modulated by the data modulator. 13. The microLED display device according to claim 12, wherein the first R, G, and B microLEDs and the second R, G, and B microLEDs in one pixel area are each driven by different thin film transistors.

Images