A chip scale semiconductor package comprises a silicon layer, a back side metal layer, and a plurality of front side pads. Each of the plurality of front side pads comprises a respective copper member and a respective solder member. A method comprises the steps of: providing a wafer; grinding the back side of the wafer forming a peripheral ring; applying a metallization process to a grinded surface; removing the peripheral ring; forming a front side seed layer; forming a front side photoresist layer; applying a photolithography process; applying a front side copper plating process; applying a front side solder plating process; stripping the front side photoresist layer; etching the front side seed layer; and applying a singulation process.

A multi-chip package includes: an interposer; a first IC chip over the interposer, wherein the first IC chip is configured to be programmed to perform a logic operation, comprising a NVM cell configured to store a resulting value of a look-up table, a sense amplifier having an input data associated with the resulting value from the NVM cell and an output data associated with the first input data of the sense amplifier, and a logic circuit comprising a SRAM cell configured to store data associated with the output data of the sense amplifier, and a multiplexer comprising a first set of input points for a first input data set for the logic operation and a second set of input points for a second input data set having data associated with the data stored in the SRAM cell, wherein the multiplexer is configured to select, in accordance with the first input data set, an input data from the second input data set as an output data for the logic operation; and a second IC chip over the interposer, wherein the first IC chip is configured to pass data associated with the output data for the logic operation to the second IC chip through the interposer.

Implementations of a semiconductor package may include a die; a first pad and a second pad, the first pad and the second pad each including a first layer and a second layer where the second layer may be thicker than the first layer. At least a first conductor may be directly coupled to the second layer of the first pad; at least a second conductor may be directly coupled to the second layer of the second pad; and an organic material may cover at least the first side of the die. The at least first conductor and the at least second conductor extend through openings in the organic material where a spacing between the at least first conductor and the at least second conductor may be wider than a spacing between the second layer of the first pad and the second layer of the second pad.

A semiconductor device includes a semiconductor substrate, a plurality of semiconductor dies, a dielectric layer, a connector, and a passivation layer. The plurality of semiconductor dies are stacked on one another and disposed over the semiconductor substrate. The dielectric layer cover a top surface and a side surface of the each of the plurality of semiconductor dies. The connector is disposed over a topmost one of the plurality of semiconductor dies. The passivation layer is disposed over the dielectric layer and laterally surrounds the connector, wherein, from a cross sectional view, an acute angle is included between an outermost side surface of the passivation layer and a bottom surface of the passivation layer.

A method of manufacturing a semiconductor package includes: forming via holes through an insulating layer to expose a redistribution conductor; forming a preliminary seed layer extending along the insulating layer and an inner surface of the via holes; forming a first photoresist layer on the preliminary seed layer which exposes first partial surfaces of the preliminary seed layer within the via holes; forming under-bump metal (UBM) vias in the via holes; forming a second photoresist layer by removing a partial region of the first photoresist layer; forming UBM pads covering the UBM vias and the second partial surfaces of the preliminary seed layer, each of the UBM pads has a convex surface protruding on a side facing away from a corresponding one of the UBM vias; removing the second photoresist layer and a partial region of the preliminary seed layer; and attaching a solder ball on the UBM pads.

Provided is a semiconductor package including a first wiring structure including a first wiring and a first wiring insulating layer on the first wiring, a first semiconductor chip on the first wiring structure, and a molding member on the first semiconductor chip, wherein the first wiring includes a first wiring via and a first wiring line, wherein the first wiring structure includes a first layer and a second layer, wherein the first wiring via is in each of the first layer and the second layer, the first wiring via in the first layer and the first wiring via in the second layer contact each other in a vertical direction, and wherein a size of the first wiring via in the first layer is less than a size of the first wiring via in the second layer.

A semiconductor device structure is provided. The semiconductor device structure includes an interconnection structure over a semiconductor substrate and a conductive pillar over the interconnection structure. The conductive pillar has a protruding portion extending towards the semiconductor substrate from a lower surface of the conductive pillar. The semiconductor device structure also includes an upper conductive via between the conductive pillar and the interconnection structure and a lower conductive via between the upper conductive via and the interconnection structure. The lower conductive via is electrically connected to the conductive pillar through the upper conductive via. The conductive pillar extends across opposite sidewalls of the upper conductive via and opposite sidewalls of the lower conductive via. A top view of an entirety of the second conductive via is separated from a top view of an entirety of the protruding portion.

A semiconductor package includes a flexible circuit board and a chip which includes a first bump group and a second bump group. First bumps of the first bump group and second bumps of the second bump group are provided to be bonded to leads on the flexible circuit board. The second bumps are designed to be longer than the first bumps in length so as to increase bonding strength of the second bumps to the leads, prevent the leads from being shifted and separated from the first and second bumps and prevent lead bonding misalignment.

A semiconductor device includes a substrate comprising a logic cell region and a peripheral region extending around the logic cell region, a logic device in the logic cell region and comprising a plurality of source/drain patterns, an upper active contact on and electrically connected to one of the source/drain patterns, a lower active contact below and electrically connected to another of the source/drain patterns, a conductive structure that penetrates the peripheral region of the substrate, a plurality of peripheral upper wiring lines in the peripheral region and connected to the conductive structure, and a plurality of peripheral lower wiring lines in the peripheral region and connected to the conductive structure opposite the peripheral upper wiring lines. A bottom surface of the conductive structure is lower than a bottom surface of the lower active contact, relative to a bottom surface of the substrate.

According to an example aspect of the present invention, there is provided a bonding structure for forming at least one electrical connection between an optoelectronic component and a photonic substrate. The bonding structure comprises a pillar structure between the optoelectronic component and the photonic substrate, and a bonding layer comprising bonding material on the pillar structure. The pillar structure for at least one individual electrical connection comprises at least two portions and at least one gap between the portions for receiving extra bonding material of the bonding layer.