The present invention provides a packaging structure and a manufacturing method thereof. The packaging structure includes a first chip, a second chip, a first heat conductor and a second heat conductor, wherein the first chip includes a first connecting surface and a first heat-conducting surface; the second chip is disposed on a side of the first connecting surface and electrically connected to the first chip, and a side of the second chip distal from the first chip includes a second heat-conducting surface; the first heat conductor is connected to the first heat-conducting surface; and the second heat conductor is connected to the second heat-conducting surface. A first heat-conducting channel is formed between the first heat-conducting surface and the first heat conductor, a second heat-conducting channel is formed between the second heat-conducting surface and the second heat conductor. Thus, the heat dissipation efficiency of the packaging structure can be significantly improved.

The present invention provides a packaging structure and a manufacturing method thereof. The packaging structure includes a first substrate, a first chip, a second chip, a first heat conductor and a second heat conductor, wherein the first substrate includes a cavity; the first chip is embedded in the cavity and includes a first connecting surface and a first heat-conducting surface that face away from each other; the second chip is disposed on a side of the first connecting surface and electrically connected to the first chip, a side of the second chip distal from the first chip includes a second heat-conducting surface on a side; and the first heat conductor is connected to the first heat-conducting surface, and the second heat conductor is connected to the second heat-conducting surface. The first substrate includes a third connecting surface that is flush with the first connecting surface.

A method of fabricating a package includes providing a mold substrate supporting dies in cavities of a fan-out substrate, detecting positions of the dies with respect to the fan-out substrate, and forming interconnection lines. At least one of the interconnection lines includes a first portion extending from the fan-out substrate to a target position on the cavity disposed between the fan-out substrate and one of the dies the one of the dies disposed at a detected position different from the target position, and a second portion extending from the one die to the fan-out substrate.

The present disclosure relates to a semiconductor package, that may include a package substrate, a base die arranged on and electrically coupled to the package substrate, and at least one power plane module arranged on the package substrate at a periphery of the base die. The power plane module may include a top surface and a bottom surface, and at least one vertical interleaving metal layer electrically coupled at the bottom surface to the package substrate. The semiconductor package may further include a semiconductor device including a first section disposed on the base die, and a second section disposed on the power plane module, wherein the second section of the semiconductor device may be electrically coupled to the at least one vertical interleaving metal layer at the top surface of the power plane module.

An electrically non-conducting film (109) comprising an oligomer comprising an arylene or heteroarylene repeating unit is disposed between a chip (105), e.g. a flip-chip, and a functional layer (101), e.g. a printed circuit board, electrically connected to the chip by electrically conducting interconnects (107). The oligomer may be crosslinked.

A semiconductor package structure includes a package substrate, a semiconductor die, an interposer, an adhesive layer, and a molding material. The semiconductor die is disposed over the package substrate. The interposer is disposed over the semiconductor die. The adhesive layer connects the semiconductor die and the interposer. The molding material surrounds the semiconductor die and the adhesive layer.

The present technology relates to a semiconductor device including: a solid-state image sensor having a pixel array unit in which a plurality of pixels each having a photoelectric conversion element is two-dimensionally arranged in a matrix; and a flexible printed circuit having wiring adapted to connect a pad portion provided on an upper surface side to be located on a light receiving surface side of the solid-state image sensor to an external terminal provided on a lower surface side opposite to the upper surface side, in which the flexible printed circuit is arranged along respective surfaces of the solid-state image sensor such that a position of an end portion located on the upper surface side becomes a position different from a position in a space above the light receiving surface.

A high-bandwidth package-on-package (HBPoP) structure includes a first package structure and a second package structure disposed over the first package structure. The first package structure includes a first package substrate, a semiconductor die, an interposer, and a molding material. The first package substrate is formed of a silicon and/or ceramic material. The semiconductor die is disposed over the first package substrate. The interposer is disposed over the semiconductor die and is formed of a silicon and/or ceramic material. The molding material is disposed between the first package substrate and the interposer and surrounds the semiconductor die.

Embodiments of the present disclosure relate to a semiconductor package, a method of forming the package and an electronic device. For example, the semiconductor package may comprise a first substrate assembly comprising a first surface and a second surface opposite the first surface. The semiconductor package may also comprise one or more chips connected or coupled to the first surface of the first substrate assembly by a first thermally and electrically conductive connecting material. In addition, the semiconductor package further comprises a second substrate assembly comprising a third surface and a fourth surface opposite the third surface, the third surface and the first surface being arranged to face each other, and the third surface being connected to one or more chips by a second thermally and electrically conductive connecting material. At least one of the first surface and the third surface is shaped to have a stepped pattern to match a surface of the one or more chips. Embodiments of the present disclosure may at least simplify the double-sided heat dissipation structure and improve the heat dissipation effect of the chip.

The present disclosure relates to a semiconductor package, that may include a package substrate, a base die arranged on and electrically coupled to the package substrate, and at least one power plane module arranged on the package substrate at a periphery of the base die. The power plane module may include a top surface and a bottom surface, and at least one vertical interleaving metal layer electrically coupled at the bottom surface to the package substrate. The semiconductor package may further include a semiconductor device including a first section disposed on the base die, and a second section disposed on the power plane module, wherein the second section of the semiconductor device may be electrically coupled to the at least one vertical interleaving metal layer at the top surface of the power plane module.