An intelligent power module includes: an encapsulating material structure; a lead frame which is at least partially encapsulated inside the encapsulating material structure, wherein all portions of the lead frame encapsulated inside the encapsulating material structure are at a same planar level; and a heat dissipation structure, which is connected to the lead frame.

The present specification provides a display device using a semiconductor light emitting element that self-assembles in a fluid, and a method for manufacturing same. The semiconductor light emitting element is a horizontal semiconductor light emitting element, and has a plurality of mesa structures on one surface thereof to enable unidirectional assembly in a fluid. Further, a transparent electrode layer can be formed on the one surface including the mesa structures to improve luminous efficiency.

In an embodiment a method for producing a lighting device includes providing a wafer assemblage having a semiconductor layer sequence arranged on a carrier substrate, separating the wafer assemblage into a plurality of first optoelectronic semiconductor chips, each comprising a section of the semiconductor layer sequence and of the carrier substrate, transferring at least some of the first optoelectronic semiconductor chips to a first auxiliary carrier, wherein the first auxiliary carrier has contact pads on a main surface, wherein the contact pads are surrounded and delimited in each case by a contour, and wherein each of the first optoelectronic semiconductor chips is arranged on a contact pad, cutting, on the first auxiliary carrier, to size the first optoelectronic semiconductor chips in order to adapt the first optoelectronic semiconductor chips to a predefined shape such that the each first optoelectronic semiconductor chip lies completely within the contour of an assigned contact pad, and transferring the first optoelectronic semiconductor chips from the first auxiliary carrier to a carrier.

A printed structure includes a destination substrate comprising two or more contact pads disposed on or in a surface of the destination substrate, a component disposed on the surface, and two or more electrically conductive connection posts. Each of the connection posts extends from a common side of the component. Each of the connection posts is in electrical and physical contact with one of the contact pads. The component is tilted with respect to the surface of the destination substrate. Each of the connection posts has a flat distal surface.

A semiconductor device package includes a redistribution layer, a plurality of conductive pillars, a reinforcing layer and an encapsulant. The conductive pillars are in direct contact with the first redistribution layer. The reinforcing layer surrounds a lateral surface of the conductive pillars. The encapsulant encapsulates the first redistribution layer and the reinforcing layer. The conductive pillars are separated from each other by the reinforcing layer.

A method of transferring a plurality of micro LEDs formed on a substrate including transferring the micro LEDs onto a first carrier substrate having a first adhesive material layer, reducing an adhesiveness of the first adhesive material layer by curing the first adhesive material layer, transferring the micro LEDs from the first carrier substrate onto a second carrier substrate having a second adhesive material layer, bonding at least a portion of the micro LEDs on the second carrier substrate to pads of a circuit board using a metal bonding layer, and separating the second carrier substrate from the micro LEDs bonded onto the circuit board.

A method includes bonding a first device die to a second device die, encapsulating the first device die in a first encapsulant, performing a backside grinding process on the second device die to reveal through-vias in the second device die, and forming first electrical connectors on the second device die to form a package. The package includes the first device die and the second device die. The method further includes encapsulating the first package in a second encapsulant, and forming an interconnect structure overlapping the first package and the second encapsulant. The interconnect structure comprises second electrical connectors.

A method for transferring electronic elements includes providing a transfer substrate including a transfer surface, and disposing electronic elements on the transfer surface; providing a target substrate including a target surface, and disposing the target substrate opposite to the transfer substrate, so that the transfer surface faces toward the target surface; providing a guiding mask including at least one guiding structure, and disposing the guiding mask between the transfer substrate and the target substrate; and releasing at least one of the electronic elements disposed on the transfer surface, and guiding the at least one of the electronic elements by the at least one guiding structure, so as to transfer the at least one of the electronic elements to the target surface of the target substrate. The present invention can achieve a high transferring yield rate even under a condition of low equipment accuracy and low equipment stability.

The application discloses a light-emitting device including a carrier which includes an insulating layer, an upper conductive layer formed on the insulating layer, a plurality of conducting vias passing through the insulating layer, and a lower conductive layer formed under the insulating layer; four light-emitting elements arranged in rows and columns flipped on the carrier; and a light-passing unit formed on the carrier and covering the four light-emitting elements; wherein each of the light-emitting elements including a first light-emitting bare die emitting a first dominant wavelength, a second light-emitting bare die emitting a second dominant wavelength, and a third light-emitting bare die emitting a third dominant wavelength; and wherein two adjacent first light-emitting bare die in a row has a first distance W1, two adjacent first light-emitting bare die in a column has a second distance W2, and W1 is the same as W2.

According to an aspect, a manufacturing method of a display device includes: obtaining a first reference position on a surface of a holding substrate based on positions of a plurality of first alignment marks of the holding substrate; and aligning the holding substrate with a transfer destination substrate such that the first reference position on the holding substrate and a second reference position on a surface of the transfer destination substrate coincide. The holding substrate is sectioned into a plurality of first sections and a plurality of second sections when viewed from one direction. Each of the first sections is provided in a part of a gap between the second sections when viewed from the one direction, has a light transmission rate higher than a light transmission rate of the second sections, and forms the first alignment mark through which light passes when viewed from the one direction.