In a general aspect, a package includes an optical sensor die fabricated in a semiconductor wafer. The optical sensor die has an optically active area on a front side of the semiconductor wafer generating a raw image signal. A transparent cover attached to the front side of the semiconductor wafer above the optically active area of the optical sensor die. An image signal processor (ISP) die processing the raw image signal is embedded in a layer of molding material attached to a back side the semiconductor wafer opposite the front side of the semiconductor wafer.

Various embodiments provide for a chip package including a carrier; a layer over the carrier; a further carrier material over the layer, the further carrier material comprising a foil; one or more openings in the further carrier material, wherein the one or more openings expose at least one or more portions of the layer from the further carrier material; and a chip comprising one or more contact pads, wherein the chip is adhered to the carrier via the one or more exposed portions of the layer.

The invention relates to a method (20) for producing an electric circuit (2) in which a circuit carrier (4) comprising a first contact surface (14) and a second contact surface (16) is provided. An insulating body (26) is placed on the circuit carrier (4), wherein the insulating body (26) at least partially covers the first contact surface (14) and the second contact surface (16), and the insulating body (26) comprises a recess (34) in the region of both contact surfaces (14, 16). A flowable electro-conductive medium (44) is introduced into the insulating body (26). The invention also relates to an electric circuit (2) and to a further method (60) for producing an electric circuit (2).

A package structure including at least one semiconductor die, an insulating encapsulant, an insulating layer, conductive pillars, a dummy pillar, a first seed layer and a redistribution layer is provided. The semiconductor die have a first surface and a second surface opposite to the first surface. The insulating encapsulant is encapsulating the semiconductor die. The insulating layer is disposed on the first surface of the semiconductor die and on the insulating encapsulant. The conductive pillars are located on the semiconductor die. The dummy pillar is located on the insulating encapsulant. The first seed layer is embedded in the insulating layer, wherein the first seed layer is located in between the conductive pillars and the semiconductor die, and located in between the dummy pillar and the insulating encapsulant. The redistribution layer is disposed over the insulating layer and is electrically connected to the semiconductor die through the conductive pillars.

A package structure and a method of manufacturing the same are provided. The package structure includes a die, a RDL structure, an encapsulant and a conductive terminal. The die is on a redistribution layer (RDL) structure. The RDL structure comprises a polymer layer and a RDL in the polymer layer. The encapsulant is on the RDL structure and laterally aside the die. The encapsulant comprises a body part and an extending part underlying the body part. The conductive terminal is electrically connected to the RDL structure and the die. The body part of the encapsulant encapsulates sidewalls of the die. The extending part of the encapsulant extends into the polymer layer.

A method of making a micro-transfer printed system includes providing a source wafer having a plurality of micro-transfer printable source devices arranged at a source spatial density; providing an intermediate wafer having a plurality of micro-transfer printable intermediate supports arranged at an intermediate spatial density less than or equal to the source spatial density; providing a destination substrate; micro-transfer printing the source devices from the source wafer to the intermediate supports of the intermediate wafer with a source stamp having a plurality of posts at a source transfer density to make an intermediate device on each intermediate support; and micro-transfer printing the intermediate devices from the intermediate wafer to the destination substrate at a destination spatial density less than the source spatial density with an intermediate stamp having a plurality of posts at an intermediate transfer density less than the source transfer density.

A package structure including at least one semiconductor die, an insulating encapsulant, an insulating layer, conductive pillars, a dummy pillar, a first seed layer and a redistribution layer is provided. The semiconductor die have a first surface and a second surface opposite to the first surface. The insulating encapsulant is encapsulating the semiconductor die. The insulating layer is disposed on the first surface of the semiconductor die and on the insulating encapsulant. The conductive pillars are located on the semiconductor die. The dummy pillar is located on the insulating encapsulant. The first seed layer is embedded in the insulating layer, wherein the first seed layer is located in between the conductive pillars and the semiconductor die, and located in between the dummy pillar and the insulating encapsulant. The redistribution layer is disposed over the insulating layer and is electrically connected to the semiconductor die through the conductive pillars.

The invention relates to a method for producing a circuit board element having at least one electronic component, which component has a connection side defined by electrical contacts or a conductive layer and is connected to a temporary carrier for positioning and embedded in an insulating material; the component is attached in a specified position directly to a plastic film as a temporary carrier, whereupon a composite layer having at least a carrier and an electrical conductor, preferably also having an insulating material, is attached on the side of the component opposite the plastic film, with the carrier facing away from the component, and thereafter the plastic film is removed; then the component is embedded in insulating material. After the embedding of the component in the insulating material, an additional composite layer is preferably attached to the component and the embedding of the component on the side opposite the first composite layer.

A method of making a micro-transfer printed system includes providing a source wafer having a plurality of micro-transfer printable source devices arranged at a source spatial density; providing an intermediate wafer having a plurality of micro-transfer printable intermediate supports arranged at an intermediate spatial density less than or equal to the source spatial density; providing a destination substrate; micro-transfer printing the source devices from the source wafer to the intermediate supports of the intermediate wafer with a source stamp having a plurality of posts at a source transfer density to make an intermediate device on each intermediate support; and micro-transfer printing the intermediate devices from the intermediate wafer to the destination substrate at a destination spatial density less than the source spatial density with an intermediate stamp having a plurality of posts at an intermediate transfer density less than the source transfer density.

A display panel includes a circuit substrate, pixel structures and a molding layer. The circuit substrate has first pad structures and second pad structures. The pixel structures are disposed above a display region of the circuit substrate. Each of at least a portion of the pixel structures includes a first light emitting diode, a first conductive block, and a first conductive connection structure. The first light emitting diode is disposed on a corresponding first pad structure. The first conductive block is disposed on a corresponding second pad structure. The first conductive connection structure electrically connects the first light emitting diode to the first conductive block. The molding layer is located above the circuit substrate and surrounds the first light emitting diode and the first conductive block. The first conductive connection structure is located on the molding layer.