An electronic device can include a first die, a second die, and an interconnect. The first die or the second die has a principal function as a power module or a memory. The first die includes a first bond pad, and the second die includes a second bond pad. The device sides of the first and second dies are along the same sides as the first and second bond pads. In an embodiment, the first die and the second die are in a chip first, die face-up configuration. The first and the second bond pads are electrically connected along a first solderless connection that includes the interconnect. In another embodiment, each material within the electrical connection between the first and the second bond pads has a flow point or melting point temperature of at least 300° C.

The present disclosure provides a chip packaging method and a chip package structure. The chip packaging method comprises: forming wafer conductive traces on a wafer active surface of a wafer; forming a protective layer having material properties on the wafer conductive traces; cutting the wafer to obtain a die and adhering the die onto a carrier; forming a molding layer encapsulating the die and having material properties; stripping off the carrier; and forming a panel-level conductive layer and a dielectric layer. The chip packaging method reduces or eliminates warpage in the panel packaging process, lowers a requirement on an accuracy of aligning the die on the panel, reduces a difficulty in the panel packaging process, and makes the packaged chip structure more durable, and thus the present disclosure is especially suitable for large panel-level package and package of a thin chip with a large electric flux.

A laser device comprises a carrier, an optoelectronic component provided on the carrier, said component being designed to emit laser radiation, and an optical element designed to form the laser radiation emitted by the optoelectronic component, wherein: the optical element has a first layer that is at least partially transparent to the laser radiation, with a first refractive index, and a second layer that is at least partially transparent to the laser radiation, with a second refractive index; the first layer being applied to the optoelectronic component and having a surface with an imprinted structure; and the second layer is applied to the first layer, on the surface (24) having the imprinted structure.

A method of manufacturing an electronic-component-embedded substrate includes forming a power-supplying metal layer on a base, forming through electrodes that are to be connected to the power-supplying metal layer on the power-supplying metal layer by an electrolytic plating method, forming a first wiring line by patterning the power-supplying metal layer, forming an interlayer insulating layer such that the interlayer insulating layer covers a portion of the first wiring line, and forming a second wiring line on at least a portion of the first wiring line and a portion of the interlayer insulating layer such that the second wiring line crosses, on the interlayer insulating layer, a portion of the first wiring line.

A semiconductor structure including a plurality of semiconductor dies, an insulating encapsulant, and a redistribution structure disposed on the semiconductor dies and the insulating encapsulant is provided. The insulating encapsulant is interposed between adjacent two of the semiconductor dies, and the insulating encapsulant includes a first portion wider than a second portion connected to the first portion. The redistribution structure includes a dielectric layer overlying the insulating encapsulant, and a conductive trace overlying the dielectric layer and opposite to the insulating encapsulant. The conductive trace includes at least one turn and is connected to a conductive terminal of one of the adjacent two of the semiconductor dies, and the conductive trace extends across the dielectric layer to reach another conductive terminal of another one of the adjacent two of the semiconductor dies.

In an embodiment, a device includes: a conductive shield on a first dielectric layer; a second dielectric layer on the first dielectric layer and the conductive shield, the first and second dielectric layers surrounding the conductive shield, the second dielectric layer including: a first portion disposed along an outer periphery of the conductive shield; a second portion extending through a center region of the conductive shield; and a third portion extending through a channel region of the conductive shield, the third portion connecting the first portion to the second portion; a coil on the second dielectric layer, the coil disposed over the conductive shield; an integrated circuit die on the second dielectric layer, the integrated circuit die disposed outside of the coil; and an encapsulant surrounding the coil and the integrated circuit die, top surfaces of the encapsulant, the integrated circuit die, and the coil being level.

Integrated fan-out packages and methods of forming the same are disclosed. An integrated fan-out package includes two dies, an encapsulant, a first metal line and a plurality of dummy vias. The encapsulant is disposed between the two dies. The first metal line is disposed over the two dies and the encapsulant, and electrically connected to the two dies. The plurality of dummy vias is disposed over the encapsulant and aside the first metal line.

A method of manufacturing an electronic device includes providing a core dielectric layer with two conductive layers formed on two opposite surfaces of the core dielectric layer, and removing at least a portion of each of the two conductive layers to respectively form an antenna pattern and a circuit pattern of a chip package at the two opposite surfaces of the core dielectric layer.

A semiconductor package includes a mold substrate, at least one first semiconductor chip in the mold substrate and including chip pads, wiring bonding pads formed at a first surface of the mold substrate and connected to the chip pads by bonding wires, and a redistribution wiring layer covering the first surface of the mold substrate and including redistribution wirings connected to the wiring bonding wirings.

Semiconductor package includes a pair of dies, a redistribution structure, and a conductive plate. Dies of the pair of dies are disposed side by side. Each die includes a contact pad. Redistribution structure is disposed on the pair of dies, and electrically connects the pair of dies. Redistribution structure includes an innermost dielectric layer, an outermost dielectric layer, and a redistribution conductive layer. Innermost dielectric layer is closer to the pair of dies. Redistribution conductive layer extends between the innermost dielectric layer and the outermost dielectric layer. Outermost dielectric layer is furthest from the pair of dies. Conductive plate is electrically connected to the contact pads of the pair of dies. Conductive plate extends over the outermost dielectric layer of the redistribution structure and over the pair of dies. Vertical projection of the conductive plate falls on spans of the dies of the pair of dies.