US20220319383A1

US20220319383A1 - Display, led chip therefor, pixel therefor, controlling method therefor, computer program therefor

Info

Publication number: US20220319383A1
Application number: US17/835,320
Authority: US
Inventors: Padraig Hughes; William Henry; Joseph O'Keeffe
Original assignee: Meta Platforms Technologies LLC
Current assignee: Meta Platforms Technologies LLC
Priority date: 2014-10-22
Filing date: 2022-06-08
Publication date: 2022-10-06
Also published as: US20210174730A1; US20170323592A1; JP2017538959A; US20200168146A1; KR20170075752A; US11386831B2; CN113972196A; EP3210241B1; EP3210241A1; US10535295B2; US10957241B2; CN107004678A; GB201418772D0; JP6741659B2; WO2016062835A1; KR102425706B1

Abstract

A display (100) comprising a plurality of LED chips (604), each LED chip (604) comprising a plurality of light emitting elements (606 a-c). Each LED chip (604) is arranged such that a first light emitting element (606 a) is configured to illuminate a sub-pixel, and a second light emitting element (606 b) is configured to illuminate a sub-pixel using substantially the same wavelength of light as the first light emitting element. There is also described an LED chip, a display pixel, a controlling method, a computer device and a computer program for a display.

Description

TECHNICAL FIELD

The invention relates to the field of displays.

BACKGROUND

ILED (Inorganic Light Emitting Diode) displays provide an alternative to the better known LCD (Liquid Crystal Display) and the OLED (Organic Light Emitting Diode) displays. An ILED display does not have any of the negative qualities of LCD or OLED displays as its display sub-pixels are based on ILED light sources and has all the advantages of this class of device. This results in a display that has the better performance characteristics of an OLED type direct view display as well as the robustness, long-life and stability that is inherent to ILED technology.
Display pixel failure and need for repair presents additional complexity to the display manufacturing process. The number of acceptable malfunctioning pixels in a display is covered by ISO-13460-2. Most display manufacturers supply class 2 displays which allow no more than two malfunctioning pixels (always on or always off) per million pixels. This requires a display sub-pixel yield of 99.998%.
For a 1920×1080 display (FHD displays), which are becoming increasingly common in mobile phones, there are 2,073,600 display pixels. Therefore, in an ILED type display, 6,220,800 individual ILED chips must be packaged (an R, G and B for each display pixel). As each device must have both p and n contacts this results in 12,144,600 contacts that must be made. As per the ISO-13460-2 standard only 4 display sub-pixels may be malfunctioning. Therefore the required yield for LED devices and interconnection is 99.99996%. Achieving this target is a significant challenge in the development of ILED type displays.
To increase the yield of displays, redundancy for chips/interconnection failure is used. In standard designs, this is done by placing two ILED chips at each display sub-pixel. Using this solution a total 12,144,600 individual ILED devices must be fabricated and “pick-and-placed” during assembly of the display. Subsequently, or as part of the pick-and-place process, interconnection must be made to 24,289,200 contacts. This approach can successfully reduce the issue of device failure as the likelihood of two failed devices/interconnections in the same display sub-pixel is smaller than the risk with a single device/interconnection. However, there are implications for the cost and complexity of the system. In addition, the presence of multiple structures (i.e. other chips) in close proximity to an emitting ILED may results in unwanted reflections and other optical interference which affect the performance of the display. An example of this is the contrast-reducing light reflection that may be produced at the surface of the ILED chips.

SUMMARY

An ILED design is described that removes the need for two individual ILEDs chips at each display sub-pixel, whilst maintaining redundancy measures and reduces the number of connections required. This results in enhanced manufacturability of this class of display as well as opening the potential for new drive schemes which may simplify the associated electronics.
According to a first aspect, there is provided a display comprising:

- a plurality of LED chips, each LED chip comprising a plurality of light emitting elements;
- wherein each LED chip is arranged such that a first light emitting element is configured to illuminate a sub-pixel, and a second light emitting element is configured to illuminate a sub-pixel using substantially the same wavelength of light as the first light emitting element.

As an option, the first and second light emitting elements are selected from any of an inorganic LED and an organic LED.
Optionally, the first light emitting element is configured to illuminate a sub-pixel of a first display pixel and the second light emitting element is configured to illuminate a sub-pixel of a second display pixel.
Each LED chip optionally comprises a plurality of Addressable Array Elements, each Addressable Array Element providing a light emitting element.
As an option, each ILED chip is integrated with a substrate, the substrate configured to provide control and power to each ILED chip.
The substrate optionally comprises any of an active matrix control and a passive matrix control.
The display optionally further comprising an optical film disposed over the plurality of LED chips, the optical film configured to direct light from each light emitting element.
As an option, each LED chip has a geometric shape such that each light emitting element is located substantially at a corner of the LED chip. As a further option, each LED chip is substantially triangular, having a light emitting element located towards each corner, and each display pixel is substantially hexagonal, each LED chip being located at an intersection of three adjacent display pixels thereby forming a sub-pixel in each of the three adjacent display pixels.
As an option, a display pixel comprises a first sub-pixel provided by a first light emitting element from a first LED chip and a second sub-pixel provided by a second light emitting element from a second LED chip, and the first and second light emitting elements share a common cathode.
Each LED chip optionally comprises a phosphor such that, in use, each LED chip can emit light at more than one wavelength.
According to a second aspect, there is provided an LED chip configured for use in a display, the LED chip comprising a first and a second light emitting element arranged to illuminate a sub-pixel, each light emitting element arranged to emit light at substantially the same wavelength.
As an option, each light emitting element is located on the ILED chip such that it forms a sub-pixel for a display pixel, and no two light emitting elements forms sub-pixels for the same display pixel.
The LED chip optionally comprises a plurality of Addressable Array Elements, each Addressable Array Element providing a light emitting element.
The LED chip is optionally integrated with a substrate, the substrate configured to provide control and power to the LED chip.
As an option, the LED chip is substantially triangular, having a light emitting element located towards each corner, such that the LED chip is locatable at an intersection of three adjacent hexagonal display pixels thereby providing a sub-pixel in each of the three adjacent display pixels.
According to a third aspect, there is provided a display pixel for a display, the display pixel comprising:
a plurality of light emitting elements located in the display pixel, each light emitting element provided by a different ILED chip.
According to a fourth aspect, there is provided a method of controlling a display, the method comprising controlling power to a plurality of light emitting elements located in a display pixel of the display, each light emitting element in the display pixel provided by a different ILED chip.
According to a fifth aspect, there is provided a computer device comprising:

- an output connecting the computer device to the display and configured to control power to a plurality of light emitting elements located in a display pixel of the display, wherein either each light emitting element in the display pixel provided by a different ILED chip or a single chip for a display pixel comprises at least two light emitting elements configured to emit light at substantially the same wavelength; and
- a processor configured to control the display.

According to a sixth aspect, there is provided a computer program comprising computer readable code which, when run on a computer device, causes the computer device to control power to a plurality of light emitting elements located in a display pixel of a display, each light emitting element in the display pixel provided by a different ILED chip.
According to a seventh aspect, there is provided a computer program product comprising a computer readable medium and a computer program according to claim 20, wherein the computer program is stored on the computer readable medium.
The computer readable medium is optionally a non-transitory computer readable medium.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates schematically a plan view of an exemplary ILED layout;

FIG. 2 illustrates schematically distinctions between LED chip types as described herein;

FIG. 3 illustrates schematically exemplary components of a display;

FIG. 4 illustrates schematically a plan view of an exemplary ILED layout having sub-pixel redundancy;

FIG. 5 illustrates schematically a plan view of an exemplary ILED layout with two corresponding Addressable Array Elements from Addressable Array Chips for each display pixel;

FIG. 6 illustrates schematically a plan view of an exemplary display having addressable LED arrays for illumination of multiple display sub pixels;

FIG. 7 illustrates schematically a close view of addressable array devices used to illuminate multiple display pixels;

FIG. 8 illustrates schematically a plan view of an “array in centre” layout; and

FIG. 9 illustrates schematically in a block diagram an exemplary computer device.

DETAILED DESCRIPTION

The following abbreviations are used in this description:

Light Emitting Diode (LED) A semiconductor device which produces light when the appropriate electrical bias is provided. It is noted that a micro-LED (μLED) may be considered a type of LED.
Emitter Any light emitting source, generally an LED. It is noted that a μLED emitter may be an emitter and may comprise only a part of a μLED device.
LED chip A piece of semiconductor material that can generate light and has been singulated from a semiconductor wafer on which it has been fabricated.
Single Emitter Chip (SEC) An LED chips with only one emitting region (or emitter). Generally the whole chip will illuminate, although this may not be the case in respect of μLEDs.
Addressable Array Chip (AAC) An LED chip which has more than one distinct light generating region (or emitter) that can be independently addressed.
Addressable Array Element (AAE) An independently addressable emitting area (or emitter) in an Addressable Array Chip.
Non-addressable Array Element (NAC) An LED chip which has more than one distinct light generating region (or emitter) which cannot be independently addressed.
Display Pixel: A component of a display that is used to build the total image. It generally consists of R, G and B sub-pixels which can be independently controlled to produce a range of colours.
Display Sub-Pixel: A sub-section of the Display Pixel which typically comprises a single colour (generally R, G or B).

Exemplary displays comprise the arrangement of R, G and B display sub pixels to form a single display pixel. A typical configuration for an ILED display 100 is highlighted in FIG. 1, where each pixel 102 comprises R, G and B chips 104 a-c packed together to provide the necessary light for each pixel 102 of the display 100. In this example, each R, G and B chip 104 a-c has one emitting area per chip or, more generally, the whole active area of the chip illuminates. These are termed Single Emitter Chips (SECs). The typical/minimum size of these R, G, B chips 104 a-c is 20 μm×20 μm although there are examples where smaller devices are used. For larger displays with moderate resolution the one to one relationship between SEC and display sub-pixel results in the requirement for a very large number of ILED chips. The inventors have appreciated that this raises significant manufacturability and cost challenges. For ultra-high resolution or very small displays, the size of the SECs may limit the area and size of the display sub-pixels and thus the overall display resolution.
FIG. 2 illustrates schematically a relationship between various ILED chip types. From FIG. 2, it can be seen that an LED chip 200 may have at least three different types: an addressable array chip 202, which comprises a plurality of addressable array elements (or emitters) 204; a non-addressable array chip 206, which comprises a plurality of array elements (or emitters) 208 that cannot be addressed individually; and a SEC 210.
Redundancy in ILED based displays reduces the risk of failed ILED devices or interconnections, which may result in failed display pixels or sub-pixels. Adding extra ILED chips at each display sub-pixel, as shown in FIG. 4, will result in double the wafer area, double the pick-and-place steps, double the electronic drivers and double the interconnections. FIG. 4 shows a display with redundancy for each sub-pixel. Other exemplary displays disclosed herein use arrays of Addressable Array Elements to reduce the above requirements. Each ILED Addressable Array Chip may contain more than one independently addressable light source. This allows for the ILED to illuminate multiple display sub-pixels from a single chip or to have a second element on the same chip in each display sub-pixel which illuminates if there is a failure in the first element.
FIG. 5 illustrates an exemplary display 500 that allows for more than the minimum number of Emitters in each display pixel 502—i.e. it provides additional Emitters in each pixel/sub pixel. The use of arrays mean that, while there are more available emitters, there is a reduction in the number of chips (and hence pick-and-place steps) when compared to other redundancy processes.
Exemplary displays disclosed herein are, therefore, a low cost and less complex route to including redundancy in an ILED display.
Exemplary methods and apparatus disclosed present displays comprising ILED chips and methods for their assembly, such that redundancy against ILED chip failure is included in the system without a significant increase in manufacturing complexity.
A display consists of a large array of individual display components that can be selectively illuminated. These components are referred to as Display Pixels. In a multi-colour display the smaller components related to the different colours are called Display sub-pixels. A display pixel comprises a plurality of display sub-pixels. In general the different colours used for sub-pixels are red, green and blue (R, G, and B).
Typically, for an LCD display, the display sub-pixels are created by colour filters and a liquid crystal optical element to selectively allow the transmission of light from a white backlight based on the pixel state. In typical ILED displays, a large array of individually addressable R, G and B ILEDs are selectively illuminated based on the pixel state to generate pixels of various colours using the intensity of light from each sub-pixel. In typical ILED display designs, Single Emitter Chips (SECs) are used. No colour filter or liquid crystal is required. As the size or resolution of a display is increased the total number of ILED chips required increases.
In the current invention, an array of Addressable Array Elements (AAEs) is fabricated on Addressable Array Chips (AACs). FIG. 2 illustrates the relationship between AAEs and AACs. These array chips reduce the number of chips that must be placed and the number of interconnections required.
In exemplary displays, the AACs are placed at an interface between two adjacent display pixels. The AACs can then be used to selectively illuminate a sub-pixel in each of the adjacent display pixels (forming the display sub-pixels of the display). As each AAC contains more than one Element (or emitter), each ILED chip can be used to illuminate more than one display sub-pixel and, hence, a number of important considerations in the manufacturing of these displays are simplified.
An example of such a layout is provided in FIG. 6, which shows a display 600 comprising a plurality of pixels 602. A plurality of ILED chips 604, each comprising a plurality of individually addressable emitters 606 a-c are arranged at the interface between adjacent display pixels 602, such that each emitter 606 a-c is in a different display pixel 602. The ILED chips 604 comprise red, green or blue emitters (typically, all the same colour on a single ILED chip 604) and they are arranged at the interface (or border) between adjacent display pixels 602 such that each display pixel comprises at least one emitter 604 a-c of each colour.
In the exemplary display 600, the ILED chips 604 comprise three emitters 606 a-c of a single colour and the display pixels 602 have a hexagonal shape. Therefore, the ILED chips 604 can be arranged such that two emitters (from different ILED chips) of each colour are in each display pixel 602, as shown in FIG. 6. As such, each sub-pixel of a display pixel 602 comprises two emitters 606 a-c that are each from a different ILED chip 604.
Exemplary displays may contain one or more of the following:

- ILED chips of a single colour;
- Each ILED chip contains a plurality of Elements (i.e. each ILED formed by an array of N×M elements (or emitters) also known as an Addressable Array Chip);
- The light from individual elements (or emitters) in an AAC can be used to illuminate one or more display sub-pixels; and
- A substrate, which enables electronic driving and control of the ILED chips or which has contacts to an electronic driver.

The ILED chips are designed as Addressable Array Chips (AACs) with more than one individually Addressable Array Elements (AAEs). The location of the elements on the AACs is dependent on the target illumination area on the display.
In the current invention ILED chips are designed and packaged to reduce the total number of LED chips required.
Shown in FIG. 1 is a top down view of a basic ILED display 100. Within each display pixel 102 are individual ILED chips 104 a-c, in this case 3 single R, G and Blue ILED chips each containing a single emitter—i.e. the chips are Single Emitter Chips (SECs). These ILED chips 104 a-c form the display sub-pixels of the display pixel 102 and each chip is individually addressable. It should be noted that for simplicity only a single light source/LED is shown for each display sub-pixel (i.e. there is no redundancy in this figure).
Shown in FIG. 4 are four display pixels (in the same configuration as that of FIG. 1) where redundancy for device failure has been included based on SECs. The addition of redundancy to the design in FIG. 1 results in double the number of chips that must be fabricated and successfully mounted/interconnected.
Standard ILED-type displays use a SEC for each Display sub-pixel. In larger displays this requires a very large number of ILED chips, pick-and-place steps and interconnections. As outlined above, more than 12 million individual LED chips are required for a 1920×1080 display. To satisfy class 2 standards, only four display sub-pixels can be defective. This results in a very significant challenge to the manufacture of such displays. In order to overcome yield issues, redundancy against device or connection failure is designed into the system. This generally is achieved by placing two SECs for each display sub-pixel. While this may reduce the number of rejected displays, it is a significant increase in the pick-and-place process steps required, the amount of ILED material required and the complexity of the electronic drive system. It should be noted that for all ILED displays fabricated a parallel method of pick-and-place is used to allow for and reduce the large number of placements. However, this does not reduce the complexity of a high number of devices to be placed as, even in a parallel process, an increase number of devices will also increase the probability of a device failure. This may be due to the failure to pick a device, to release a device, a device being placed in an incorrect location or a failure to electrically connect to the device.
An example of a simple system without redundancy is shown in FIG. 1 while a system with redundancy included is shown in FIG. 4.
In exemplary methods and apparatus disclosed herein, ILED chips comprise Addressable Array Chips (AAC) used to illuminate the display pixels. In one exemplary apparatus, an AAC may contain two Addressable Array Elements (AAE) (e.g. ILED emitters). The ILED emitters can be selectively illuminated, such that one or both of the ILED emitters can be illuminated. In the case of the failure of an Element on the AAC, the other active Element on the device can be used. The approach of using an AAC will reduce by 50% the number of pick-and-place steps for the assembly of the displays. As the AAC may be fabricated with a common ground line between the two active elements, the current invention would require only three connections per display sub-pixel (two anodes and one cathode). In contrast the standard solution requires four connections per display sub-pixel, an increase of 33%, to connect the one anode and one cathode on each LED.
In another exemplary display, each AAC may comprise more than two Addressable Array Elements (or emitters). These AACs can be subsequently positioned such that each element on an AAC illuminates a different display sub-pixel, each on an adjacent display pixel. In this design the number of pick-and-place steps and interconnections is greatly reduced while maintaining the redundancy of this system. An example of such as design is shown in FIG. 6. A closer look at the display pixels are shown in FIG. 7. In these figures, the boundaries of the display pixels are shown by the dotted hexagon shape.
Referring to FIG. 7, a display Pixel B 700 can be illuminated by a blue Element on Addressable Array Chip 1 702 or a blue Element on Addressable Array Chip 2 704. Therefore, redundancy for the blue display sub-pixel is provided by Addressable Array Chip 2 704 if the left most emitter on Addressable Array Chip 1 702 fails. Similarly for the red and green display sub-pixels, redundancy is provided by emitters on other Addressable Array Chips. It is noted that the number of chips required to provide redundancy in the above design is reduced compared to known redundancy methods. For Display Pixel B a total of six Addressable Array Chips are required. However, these Addressable Array Chips are sharing their Addressable Array Elements with other Display Pixels. Each Addressable Array Chip provides a third of its emitters to Display Pixel B. Therefore it can be said that two Addressable Array Chips are required for each Display Pixel—in contrast to three in otherdesigns with no redundancy (FIG. 1) or six in other designs with redundancy (FIG. 4).
Each of the Addressable Array Chips may also share a cathode connection. Therefore, the total number of connections is reduced. For each display pixel there will be six anodes (one for each of the emitters/active regions) and a third of six cathodes (which are shared) resulting in eight interconnections. In contrast other ILED displays with redundancy require twelve interconnections.
Note that the positioning of the Addressable Array Element in the display sub-pixels will not be a significant issue. The relative position and pitch of the Addressable Array Elements is of greater importance than the actual location. Due to the high resolution of current generation displays, the distance between a failed Addressable Array Element and its replacement will be in the range from 30-200 μm. This displacement will not be significant especially when the failed pixels are randomly distributed across the screen. In addition when a replacement AAE must be used due to the failure of the “preferred” AAE then other “replacement” AAEs may also be selected. The number of “replacement” pixels used could be decreased as distance increases from the malfunctioning pixel. Hence the effect of positional variation caused by a failed Element would be gradual and not obvious to human perception.
For the above layout there may exist a “preferred” Addressable Array Element that could be illuminated such that the pitch between display sub-pixels is optimized for viewer experience. In the majority of cases this preferred Element will be functioning and can be used. For example, in a 1920×1080 display there are 6,220,800 display sub-pixels. If 10 of these display sub-pixels were malfunctioning then, without redundancy, this display would be discarded. However, using the current invention these malfunctioning pixels could be corrected with only 0.00016% of Addressable Array Elements in their non-optimum location. Note that these non-optimum Elements would, in all probability, be randomly distributed around the display.
Another feature of an ILED display using Addressable Array Chips is the use of optical films or elements to position the light appropriately. Such films have the ability to direct light with high efficiency. In the current invention such films may be used to bring the light from emitters at the edge of a display pixel to its centre. This would allow for the optimization of the spatial distribution of the light within the display pixel. In effect, this optical film would position the light from the “replacement” Element such that it was close to the position of the “preferred” Element or the appropriate position in the display sub-pixel.
An alternative method of producing three colour display sub-pixels is the conversion of a monochromatic light source into more than one colour. This can be achieved using a number of materials including traditional phosphors (for example Yttrium aluminium garnet, Y₃Al₅O₁₂), quantum dots or colloid phosphors. For devices such as the LED with a pixel diameter in the order of less than 50 μm, a quantum dot solution would provide adequate uniformity. For such a design, a blue ILED Addressable Array Chip containing three Addressable Array Elements may be fabricated in a single colour. Quantum dot materials, which convert to two wavelengths, would be placed in the path of the emitted light for two of these Elements. The effect of the quantum dots phosphors would result in light at three wavelengths being produced by a single chip.
This Addressable Array Chip could form the totality of the display sub-pixel or two could be used to provide redundancy.
Shown in Table 1 is a comparison of the current invention and a standard ILED display with redundancy in a number of the major factors associated with Display manufacturing. It is assume that each anode and cathode contact requires 10 um². It is further assumed that both contacts are on the same side of the device. While contacting to opposite sides of an ILED chips is possible, it is problematic as it restricts the area available for light extraction from the light source. An example of the “Array in Centre” design is shown in FIG. 8. FIG. 4 shows a standard ILED design with redundancy and FIG. 6 shows the “Array at edges” design.

TABLE 1

Overview of various parameters for the fabrication of
1920 × 1080 ILED type display in standard design
and using the design proposed in the current invention.

	Pick & Place	Chip area
Design	placements	(mm²)	Interconnections

Standard	12,441,600	248.0	24,883,200
Array in centre	6,220,800	186.6	18,662,400
Array at edges	4,147,200	165.9	16,588,800

In one exemplary display, the ILED Addressable Array Chips are towards the centre of the display pixel as shown in FIG. 8. In another exemplary display, the ILED Addressable Array Chips are towards the edge of the display pixel and the emitters of an AAC may illuminate more than one display pixel. In another exemplary display, the light from the ILED Addressable Array Chips is coupled to an optical film which positions the light appropriately before it emerges from the display.
In another exemplary display, ILED Addressable Array Chips with quantum dot phosphors would be used to produce multiple wavelengths from a single chip.
FIG. 9 illustrates schematically in a block diagram an exemplary computer device 900. The computer device is connected to a display 902 that comprises display pixels, for example, as shown in FIGS. 5 to 8. A processor 904 controls the display and selectively provides power to the ILED Addressable Array Chips of the display. A non-transitory computer readable medium in the form of a memory 906 is provided, which is used for storing a program 908 which, when executed by the processor 904, causes the processor to behave as described above. Note that the program may be provided from an external computer readable medium 910, such as a CD, a flash drive, a carrier wave and so on.
Whilst specific embodiments of the invention are described above, it will be appreciated that a number of modifications and alterations may be made thereto without departing from the scope of the invention as defined in the appended claims.

Numbered Clauses

1. An ILED type display such that there is more than 1 Addressable Array Elements for each display sub-pixel and therefore provides redundancy against device failure and contains:
a. A plurality of ILED chips
b. Each ILED chip contains a plurality of Addressable Array Elements (i.e. each ILED chip is an Addressable Array Chip).
c. The light from individual Addressable Array Elements in an Addressable Array Chip can be used to illuminate one or more display sub-pixels.
2. As per clause 1, where the Addressable Array Chips are integrated with a substrate which enables electronic driving and control of the ILED chips or which has contacts to an electronic driver.
3. As per clause 1, where an optical film is used to position the light from a plurality of Addressable Array Elements to the appropriate positions within the display pixel.
4. As per clause 1, where the ILED Addressable Array Elements Chips are at multiple wavelength for example red, green and blue.
5. As per clause 1, the ILED Addressable Array Chips are in geometric shapes with the emitters primarily at the corners.
6. As per clause 1, a display layout whereby an ILED Addressable Array Chips is placed towards the centre of a display sub-pixel and the plurality of Addressable Array Elements can be selectively illuminated such that redundancy against device failure is provided.
7. An ILED display layout whereby an ILED Addressable Array Chips is placed towards the edge of multiple display pixels such that the plurality of Addressable Array Elements may illuminate more than 1 display sub-pixel and as such, provide redundancy.
8. An ILED display such that the Elements providing redundancy share a common cathode on the Addressable Array Chip.
9. As per clause 2, where the control substrate is an active matrix.
10. As per clause 2, where the control substrate is a passive matrix.
11. As per clause 1, where phosphors are integrated with the ILED Addressable Array Chips such that more than one wavelength is produce by each chip.
12. An optical film which is integrated with an ILED array such that the light is controlled before it emerges from the display sub-pixel.

Claims

1-22. (canceled)

23. A display comprising:

a substrate; and

a plurality of separate and singulated light emitting diode (LED) chips on the substrate, each of the LED chips comprising:

a first subset of the light emitting elements comprising first quantum dots or colloid phosphors by which light emitted by the first subset of the light emitting elements is converted into a first color, and

a second subset of the light emitting elements that emit light without passing light through the first quantum dots or colloid phosphors.

24. The display of claim 23, wherein each of the LED chips further comprises a third subset of light emitting elements comprising a third subset of the light emitting elements comprising second quantum dots of colloid phosphors by which light emitted by the second subset of the light emitting elements is converted into a second color different from the first color.

25. The display of claim 24, wherein light emitting elements of more than one of the LED chips form a single pixel.

26. The display of claim 24, wherein each of the LED chips form a single pixel.

27. The display of claim 24, wherein each of the LED chips have a triangular shape with the first subset, the second subset and the third subset at corners.

28. The display of claim 23, wherein an anode contact and a cathode contact of each of the LED chips are at a same side of each of the LED chips.

29. The display of claim 23, wherein each of the first and second subsets is individually addressable.

30. A method of operating a display, comprising:

emitting first light of a first color from a first light emitting element of each of a plurality of separate and singulated light emitting diode (LED) chips on a substrate;

emitting second light of the first color from a second light emitting element of each of the LED chips;

passing the second light through first quantum dots or colloid phosphors to convert the second light to a second color different from the first color; and

bypassing the quantum dots or colloid phosphors by the first light.

31. The method of claim 30, further comprising:

emitting third light of the first color from a third light emitting element of each of the LED chips; and

passing the third light through second quantum dots or colloid phosphors to convert the third light to a third color different from the first color and the second color.

32. The method of claim 31, wherein each of the LED chips form a single pixel.

33. The method of claim 31, wherein each of the LED chips have a triangular shape with the first subset, the second subset and the third subset at corners.

34. The method of claim 30, wherein an anode contact and a cathode contact of each of the LED chips are at a same side of each of the LED chips.

35. The method of claim 30, wherein each of the first and second emitting elements is individually addressable.