A semiconductor package includes a support member, a semiconductor chip arranged in the support member such that a front surface and a backside surface of the semiconductor chip are exposed from a second surface of the support member and a first surface opposite to the second surface respectively, a lower redistribution wiring layer covering the second surface of the support member and including first redistribution wirings electrically connected to chip pads provided at the front surface of the semiconductor chip and vertical connection structures of the support member respectively, and an upper redistribution wiring layer covering the first surface of the support substrate, and including second redistribution wirings electrically connected to the vertical connection structures and a thermal pattern provided on the exposed backside surface of the semiconductor chip.

A semiconductor package includes a support member, a semiconductor chip arranged in the support member such that a front surface and a backside surface of the semiconductor chip are exposed from a second surface of the support member and a first surface opposite to the second surface respectively, a lower redistribution wiring layer covering the second surface of the support member and including first redistribution wirings electrically connected to chip pads provided at the front surface of the semiconductor chip and vertical connection structures of the support member respectively, and an upper redistribution wiring layer covering the first surface of the support substrate, and including second redistribution wirings electrically connected to the vertical connection structures and a thermal pattern provided on the exposed backside surface of the semiconductor chip.

A chip structure is provided. The chip structure includes a substrate. The chip structure includes a redistribution layer over the substrate. The chip structure includes a bonding pad over the redistribution layer. The chip structure includes a shielding pad over the redistribution layer and surrounding the bonding pad. The chip structure includes an insulating layer over the redistribution layer and the shielding pad. The chip structure includes a bump over the bonding pad and the insulating layer. A sidewall of the bump is over the shielding pad.

A 3D stack includes a first chip having first interconnection pads of rectangular section, the first interconnection pads having a first pitch in a first direction and a second pitch in a second direction perpendicular to the first direction; and a second chip having second interconnection pads, the second interconnection pads having a third pitch in the first direction and a fourth pitch in the second direction, at least one part of the second interconnection pads being in contact with the first interconnection pads to electrically couple the first and second chips. The first interconnection pads have a first dimension in the first direction equal to m times the third pitch and a second dimension in the second direction equal to n times the fourth pitch. The first interconnection pads are separated two by two in the first direction by a first distance equal to q times the third pitch.

A 3D stack includes a first chip having first interconnection pads of rectangular section, the first interconnection pads having a first pitch in a first direction and a second pitch in a second direction perpendicular to the first direction; and a second chip having second interconnection pads, the second interconnection pads having a third pitch in the first direction and a fourth pitch in the second direction, at least one part of the second interconnection pads being in contact with the first interconnection pads to electrically couple the first and second chips. The first interconnection pads have a first dimension in the first direction equal to m times the third pitch and a second dimension in the second direction equal to n times the fourth pitch. The first interconnection pads are separated two by two in the first direction by a first distance equal to q times the third pitch.

A display apparatus includes a first base substrate defining: an outer edge thereof at which a side surface is exposed, and an upper surface thereof connected to the outer edge; first and second guiding dams on the upper surface and extending from an inside of the first base substrate to the outer edge; a first signal line on the upper surface and extending between the first and second guiding dams from the inside of the first base substrate to the outer edge thereof; and a first side pad connected to the first signal line. The first side pad includes a first horizontal portion on the upper surface and extending between the first and second guiding dams, in a top plan view, and the first horizontal portion extending to define a first vertical portion which is disposed on the side surface.

A chip structure is provided. The chip structure includes a substrate. The chip structure includes a redistribution layer over the substrate. The chip structure includes a bonding pad over the redistribution layer. The chip structure includes a shielding pad over the redistribution layer and surrounding the bonding pad. The chip structure includes an insulating layer over the redistribution layer and the shielding pad. The chip structure includes a bump over the bonding pad and the insulating layer. A sidewall of the bump is over the shielding pad.

An imaging device includes a first chip (72). The first chip includes first and second pixels including respective first and second photoelectric conversion regions (PD) that convert incident light into electric charge. The first chip includes a first connection region for bonding the first chip to a second chip (73) and including a first connection portion (702, 702d) overlapped with the first photoelectric conversion region in a plan view, and a second connection portion overlapped with the second photoelectric conversion region in the plan view. The first photoelectric region receives incident light of a first wavelength, and the second photoelectric conversion region receives incident light of a second wavelength that is greater than the first wavelength. The first connection portion overlaps an area of the first photoelectric conversion region that is larger than an area of the second photoelectric conversion region overlapped by the second connection portion.

A display apparatus includes a first base substrate defining: an outer edge thereof at which a side surface is exposed, and an upper surface thereof connected to the outer edge; first and second guiding dams on the upper surface and extending from an inside of the first base substrate to the outer edge; a first signal line on the upper surface and extending between the first and second guiding dams from the inside of the first base substrate to the outer edge thereof; and a first side pad connected to the first signal line. The first side pad includes a first horizontal portion on the upper surface and extending between the first and second guiding dams, in a top plan view, and the first horizontal portion extending to define a first vertical portion which is disposed on the side surface.

A method for manufacturing semiconductor device includes preparing a semiconductor wafer including a first semiconductor substrate and a first through silicon via; removing a trim region of the first semiconductor substrate along an edge portion of the semiconductor wafer to form a remaining edge region; attaching the semiconductor wafer to a carrier substrate, wherein the remaining edge region is in contact with the carrier substrate; forming an edge protection layer along the remaining edge region; exposing the first through silicon via by removing a predetermined depth of the first semiconductor substrate; forming a second final passivation layer to expose the upper surface of the first through silicon via; forming a plurality of first upper connection pads on the second final passivation layer; and dicing the semiconductor wafer into a plurality of first semiconductor chips.