A redistribution circuit structure electrically connected to at least one conductor underneath is provided. The redistribution circuit structure includes a dielectric layer, an alignment, and a redistribution conductive layer. The dielectric layer covers the conductor and includes at least one contact opening for exposing the conductor. The alignment mark is disposed on the dielectric layer. The alignment mark includes a base portion on the dielectric layer and a protruding portion on the base portion, wherein a ratio of a maximum thickness of the protruding portion to a thickness of the base portion is smaller than 25%. The redistribution conductive layer is disposed on the dielectric layer. The redistribution conductive layer includes a conductive via, and the conductive via is electrically connected to the conductor through the contact opening. A method of fabricating the redistribution circuit structure and an integrated fan-out package are also provided.

An integrated fan-out package including a die, an insulating encapsulation, a filler, and a redistribution circuit structure is provided. The insulating encapsulation encapsulates sidewalls of the die, and the insulating encapsulation includes a recess on a top surface thereof. The filler covers the top surface of the insulating encapsulation and is being at least partially filled in the recess. The redistribution circuit structure covers an active surface of the die and the filler while being electrically connected to the die. The redistribution structure includes a dielectric layer covering the die and the filler. In addition, a method of manufacturing integrated fan-out packages is also provided.

A wiring (3) comprising electrical conductors (4, 5, 6, 7) is formed in a dielectric layer (2) on or above a semiconductor substrate (1), an opening is formed in the dielectric layer to uncover a contact pad (8), which is formed by one of the conductors, and a further opening is formed in the dielectric layer to uncover an area of a further conductor (5), separate from the contact pad. The further opening is filled with an electrically conductive material (9), and the dielectric layer is thinned from a side opposite the substrate, so that the electrically conductive material protrudes from the dielectric layer.

A semiconductor device includes a semiconductor layer that has a main surface, an electrode pad that is formed on the main surface, a rewiring that has a first wiring surface connected to the electrode pad and a second wiring surface positioned on a side opposite to the first wiring surface and being roughened, the rewiring being formed on the main surface such as to be drawn out to a region outside the electrode pad, and a resin that covers the second wiring surface on the main surface and that seals the rewiring.

A semiconductor package includes a processor die, a storage module and a package substrate. The storage module includes an array of cache units and an array of memory units stacked over one another, and electrically connected to the processor die, wherein the array of cache units is configured to hold copies of data stored in the array of memory units and frequently used by the processor die. The package substrate is on which the processor die and the storage module are disposed.

A semiconductor package including a first stack; a plurality of TSVs passing through the first stack; a second stack on the first stack and including a second surface facing a first surface of the first stack; a first pad on the first stack and in contact with the TSVs; a second pad on the second stack; a bump connecting the first and second pads; a first redundancy pad on the first surface of the first stack, spaced apart from the first pad, and not in contact with the TSVs; a second redundancy pad on the second surface of the second stack and spaced apart from the second pad; and a redundancy bump connecting the first redundancy pad and the second redundancy pad, wherein the first pad and first redundancy pad are electrically connected to each other, and the second pad and second redundancy pad are electrically connected to each other.

An integrated circuit chip includes a substrate on which a standard cell is disposed. The integrated circuit chip includes a plurality of power bumps including a plurality of first power bumps and a plurality of second power bumps, the plurality of power bumps. disposed to have a staggered arrangement in a central region of one surface of the integrated circuit chip, and connected to provide power to the standard cell; a first metal wiring disposed below the plurality of first power bumps and electrically connected to the plurality of first power bumps, at least a part of the first metal wiring overlapping the plurality of first power bumps from a plan view; and a second metal wiring horizontally separated from the first metal wiring, disposed below the plurality of second power bumps, and electrically connected to the plurality of second power bumps, at least a part of the second metal wiring overlapping the plurality of second power bumps from the plan view. The plurality of first power bumps are disposed along a first line extending in a first direction parallel to a first diagonal direction of the integrated circuit chip, and along a second line extending in a second direction parallel to a second diagonal direction of the integrated circuit chip different from the first diagonal direction, the first diagonal direction and second diagonal direction being diagonal with respect to edges of the integrated circuit chip, and the plurality of second power bumps are disposed along a third line spaced apart from the first line and extending in the first direction, and along a fourth line spaced apart from the second line and extending in the second direction.

A semiconductor device has a top metal layer, a first passivation layer over the top metal layer, a first redistribution layer over the first passivation layer, a first polymer layer, and a first conductive via extending through the first polymer layer. The first polymer layer is in physical contact with the first passivation layer.

Apparatuses and methods for coupling semiconductor devices are disclosed. In a group of semiconductor devices (e.g., a stack of semiconductor devices), a signal is provided to a point of coupling at an intermediate semiconductor device of the group, and the signal is propagated away from the point of coupling over different (e.g., opposite) signal paths to other semiconductor devices of the group. Loading from the point of coupling at the intermediate semiconductor device to other semiconductor devices of a group may be more balanced than, for example, having a point of coupling at semiconductor device at an end of the group (e.g., a lowest semiconductor device of a stack, a highest semiconductor device of the stack, etc.) and providing a signal therefrom. The more balanced topology may reduce a timing difference between when signals arrive at each of the semiconductor devices.

A semiconductor package and a method of forming a semiconductor package with one or more dies over an interposer are provided. In some embodiments, the semiconductor package has a plurality of through substrate vias (TSVs) extending through an interposer substrate. A redistribution structure is arranged over a first surface of the interposer substrate, and a first die is bonded to the redistribution structure. An edge of the first die is beyond a nearest edge of the interposer substrate. A second die is bonded to the redistribution structure. The second die is laterally separated from the first die by a space.