In a described example, a packaged device includes a substrate having a device mounting surface including a first layer of conductive material having a first thickness less than a substrate thickness, the substrate having a second layer of the conductive material having a second thickness less than the substrate thickness. A first semiconductor device is mounted to a first area of the device mounting surface; and a second semiconductor device is mounted to a second area on the device mounting surface and spaced from the first semiconductor device. At least two connectors are formed of the first layer of the substrate having first ends coupled to one of first bond pads on the first semiconductor device and the at least two connectors having second ends coupled to one of second bond pads on the second semiconductor device.

A light emitting device including at least one LED stack, electrode pads disposed on the LED stack, and cantilever electrodes disposed on the electrode pads, respectively, in which each of the cantilever electrodes has a fixed edge that is fixed to one of the electrode pads and a free standing edge that is spaced apart from the one of the electrode pads.

A method of using an optoelectronic semiconductor stamp to manufacture an optoelectronic semiconductor device comprises the following steps: a preparation step: preparing at least one optoelectronic semiconductor stamp group and a target substrate, wherein each optoelectronic semiconductor stamp group comprises at least one optoelectronic semiconductor stamp, each optoelectronic semiconductor stamp comprises a plurality of optoelectronic semiconductor components disposed on a heat conductive substrate, each optoelectronic semiconductor component has at least one electrode, and the target substrate has a plurality of conductive portions; an align-press step: aligning and attaching at least one optoelectronic semiconductor stamp to the target substrate, so that the electrodes are pressed on the corresponding conductive portions; and a bonding step: electrically connecting the electrodes to the corresponding conductive portions.

The present invention provides a display device comprising: a substrate; a wiring electrode disposed on the substrate; a plurality of semiconductor light emitting elements each provided with a conductive electrode electrically connected to the wiring electrode; and an anisotropic conductive layer which is disposed between the conductive electrodes and the wiring electrode and formed of a mixture of conductive particles and an insulating material, wherein the conductive electrodes are provided with a protrusion part protruding toward the wiring electrode.

A removal module for removing a mis-assembled semiconductor light emitting diode includes a housing having an inner space formed by an upper plate having a nozzle hole and a lower plate spaced apart from the upper plate; a fluid supply part configured to supply a fluid outside the housing to the inner space; and a fluid control part configured to control spray of the fluid supplied to the inner space through the nozzle hole by adjusting a pressure of the inner space.

A display device according to an embodiment includes a pixel and a bank. The pixel includes sub-pixels and an emission area including sub-emission areas corresponding to the sub-pixels. The bank surrounds the emission area. The pixel includes electrodes disposed in each of the sub-emission areas, at least one light emitting element disposed in each of the sub-emission areas, and bank patterns disposed under the electrodes, the bank patterns overlapping a portion of the electrodes. The bank patterns include a first bank pattern including a first valley, the first bank pattern being disposed in a first edge area of the emission area in a first direction. The bank patterns include a second bank pattern including a second valley, the second bank pattern being disposed in a second edge area of the emission area in the first direction.

A semiconductor device includes: an insulated circuit substrate including first and second conductive layers on a top surface side; a first semiconductor chip mounted on the first conductive layer; a second semiconductor chip mounted on the second conductive layer; a printed circuit board including a first lower-side wiring layer arranged to be opposed to the first semiconductor chip, and a second lower-side wiring layer arranged to be opposed to the second semiconductor chip, the printed circuit board being provided with a curved part curved toward the insulated circuit substrate; a first connection member arranged to connect the first semiconductor chip with the first lower-side wiring layer; a second connection member arranged to connect the second semiconductor chip with the second lower-side wiring layer; and a third connection member arranged to connect the first conductive layer with the second lower-side wiring layer at the curved part.

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.