A microLED display includes a first main substrate, microLEDs disposed above the first main substrate, a first light blocking layer disposed above the first main substrate to define emission areas, a light guiding layer disposed in the emission areas, and a plurality of connecting structures disposed in the emission areas respectively and electrically connected with the microLEDs.

Disclosed is a light emitting diode (LED) assembly having vertical type micro LEDs which are vertically aligned and is capable of significantly improving light efficiency, a light quantity, and an integration degree through optimized alignment of the vertical type micro LEDs each having a nano size or micro size. The LED assembly includes a substrate provided with a plurality of through holes formed in a thickness direction, micro LEDs each formed in a vertical type in which a vertical width is greater than a lateral width, and aligned in an upright state by being at least partially inserted into the through holes, and a first electrode deposited on a lower surface of the substrate to be connected to a first conductive layer and a second electrode deposited on an upper surface of the substrate to be connected to a second conductive layer.

Disclosed is a light emitting diode (LED) assembly having vertical type micro LEDs which are vertically aligned and is capable of significantly improving light efficiency, a light quantity, and an integration degree through optimized alignment of the vertical type micro LEDs each having a nano size or micro size. The LED assembly includes a substrate provided with a plurality of through holes formed in a thickness direction, micro LEDs each formed in a vertical type in which a vertical width is greater than a lateral width, and aligned in an upright state by being at least partially inserted into the through holes, and a first electrode deposited on a lower surface of the substrate to be connected to a first conductive layer and a second electrode deposited on an upper surface of the substrate to be connected to a second conductive layer.

A display apparatus can include a first transistor disposed on a substrate, the first transistor including a first active layer made of low temperature polycrystalline silicon (LTPS); a circuit insulating layer disposed on the first transistor; a second transistor disposed on the circuit insulating layer, the second transistor including a second active layer made of an oxide semiconductor; a driving transistor disposed on the circuit insulating layer, the driving transistor having a back channel etch structure (BCE) and an active layer made of the oxide semiconductor; and a light emitting diode electrically connected to the driving transistor, in which the circuit insulating layer is disposed between the first transistor and the driving and second transistors.

A display apparatus can include a first transistor disposed on a substrate, the first transistor including a first active layer made of low temperature polycrystalline silicon (LTPS); a circuit insulating layer disposed on the first transistor; a second transistor disposed on the circuit insulating layer, the second transistor including a second active layer made of an oxide semiconductor; a driving transistor disposed on the circuit insulating layer, the driving transistor having a back channel etch structure (BCE) and an active layer made of the oxide semiconductor; and a light emitting diode electrically connected to the driving transistor, in which the circuit insulating layer is disposed between the first transistor and the driving and second transistors.

A light emitting module includes: a plurality of light emitting elements each having a primary light emitting surface and a lateral surface; a plurality of wavelength conversion members arranged respectively on the primary light emitting surfaces of the plurality of light emitting elements; and a lightguide plate having a first primary surface and a second primary surface and arranged continuously on the plurality of wavelength conversion members so that the second primary surface faces the plurality of wavelength conversion members, wherein the lightguide plate includes a plurality of recessed portions located on the second primary surface, and a lateral surface of at least one of the plurality of wavelength conversion members is partially in contact with an inner lateral surface of at least one of the plurality of recessed portions.

A light emitting module includes: a plurality of light emitting elements each having a primary light emitting surface and a lateral surface; a plurality of wavelength conversion members arranged respectively on the primary light emitting surfaces of the plurality of light emitting elements; and a lightguide plate having a first primary surface and a second primary surface and arranged continuously on the plurality of wavelength conversion members so that the second primary surface faces the plurality of wavelength conversion members, wherein the lightguide plate includes a plurality of recessed portions located on the second primary surface, and a lateral surface of at least one of the plurality of wavelength conversion members is partially in contact with an inner lateral surface of at least one of the plurality of recessed portions.

A light emitting device includes a mount board that includes a wiring pattern on an upper surface, and light emitting elements that are mounted at corresponding one of mounting positions on the wiring pattern to be connected in series and/or in parallel to each other through the wiring pattern. The light emitting elements each include a pair of electrodes on a back surface side thereof. The mounting positions include four or more connection terminals that are electrically separated from each other to connect the electrodes of their corresponding light emitting element to each other. Series connection and parallel connection numbers are determined in accordance with orientations of the light emitting elements in which each electrode straddles at least adjacent two of the four or more connection terminals that are spaced away from and adjacent to each other.

Provided are an optoelectronic apparatus including an on-chip optoelectronic diode capable of receiving and emitting light, and a method of manufacturing the same.

A display device having a partially transparent substrate with a plurality of electrical consumers arranged in series having first and second contacts for applying a first and a second potential, and a third contact for receiving a control signal. A partially transparent electrically conductive layer electrically contacts the electrical consumers. A first and second connector for applying the first and the second potential to the conductive layer, and a third connector for applying the control signal. The conductive layer is attached to the transparent substrate with the three segments insulated from one another. A first and second segment are distanced from one another by a third segment. The first segment contacts the first connector and the first contact of one or more consumers, and the second segment contacts the second connector and the second contact of a consumers. The third segment contacts a third contact of an electrical consumer.