A semiconductor device and a method of forming the same are provided. The semiconductor device includes a die structure including a plurality of die regions and a plurality of first seal rings. Each of the plurality of first seal rings surrounds a corresponding die region of the plurality of die regions. The semiconductor device further includes a second seal ring surrounding the plurality of first seal rings and a plurality of connectors bonded to the die structure. Each of the plurality of connectors has an elongated plan-view shape. A long axis of the elongated plan-view shape of each of the plurality of connectors is oriented toward a center of the die structure.

A semiconductor device and a method of forming the same are provided. The semiconductor device includes a die structure including a plurality of die regions and a plurality of first seal rings. Each of the plurality of first seal rings surrounds a corresponding die region of the plurality of die regions. The semiconductor device further includes a second seal ring surrounding the plurality of first seal rings and a plurality of connectors bonded to the die structure. Each of the plurality of connectors has an elongated plan-view shape. A long axis of the elongated plan-view shape of each of the plurality of connectors is oriented toward a center of the die structure.

Structures and formation methods of a package structure are provided. The package structure includes a semiconductor die and a substrate bonded to the semiconductor die through a first bonding structure and a second bonding structure therebetween. The first bonding structure and the second bonding structure are next to each other and the second bonding structure is wider than the first bonding structure. The first bonding structure has a first under bump metallurgy (UBM) structure and a first solder bump thereon, and the second bonding structure has a second UBM structure and a second solder bump thereon. The second UBM structure has a maximum width larger than that of the first UBM structure, and the second solder bump has a maximum width larger than that of the first solder bump.

Structures and formation methods of a package structure are provided. The package structure includes a semiconductor die and a substrate bonded to the semiconductor die through a first bonding structure and a second bonding structure therebetween. The first bonding structure and the second bonding structure are next to each other and the second bonding structure is wider than the first bonding structure. The first bonding structure has a first under bump metallurgy (UBM) structure and a first solder bump thereon, and the second bonding structure has a second UBM structure and a second solder bump thereon. The second UBM structure has a maximum width larger than that of the first UBM structure, and the second solder bump has a maximum width larger than that of the first solder bump.

A system and method for stacking semiconductor devices in three dimensions is provided. In an embodiment two or more semiconductor dies are attached to a carrier and encapsulated. Connections of the two or more semiconductor dies are exposed, and the two or more semiconductor dies may be thinned to form connections on an opposite side. Additional semiconductor dies may then be placed in either an offset or overhanging position.

A semiconductor chip is mounted on a mounting substrate. The semiconductor chip includes plural first bumps on a surface facing the mounting substrate. The plural first bumps each have a shape elongated in a first direction in plan view and are arranged in a second direction perpendicular to the first direction. The mounting substrate includes, on a surface on which the semiconductor chip is mounted, at least one first land connected to the plural first bumps. At least two first bumps of the plural first bumps are connected to each first land. The difference between the dimension of the first land in the second direction and the distance between the outer edges of two first bumps at respective ends of the arranged first bumps connected to the first land is 20 m or less.

A semiconductor chip is mounted on a mounting substrate. The semiconductor chip includes plural first bumps on a surface facing the mounting substrate. The plural first bumps each have a shape elongated in a first direction in plan view and are arranged in a second direction perpendicular to the first direction. The mounting substrate includes, on a surface on which the semiconductor chip is mounted, at least one first land connected to the plural first bumps. At least two first bumps of the plural first bumps are connected to each first land. The difference between the dimension of the first land in the second direction and the distance between the outer edges of two first bumps at respective ends of the arranged first bumps connected to the first land is 20 m or less.

A system and method for stacking semiconductor devices in three dimensions is provided. In an embodiment two or more semiconductor dies are attached to a carrier and encapsulated. Connections of the two or more semiconductor dies are exposed, and the two or more semiconductor dies may be thinned to form connections on an opposite side. Additional semiconductor dies may then be placed in either an offset or overhanging position.

An electronic device has a plurality of integrated circuits fixed to a support between transmitting and receiving antennas. An integrated circuit generates a synchronization signal supplied to the other integrated circuits. Each integrated circuit is formed in a die integrating electronic components and overlaid by a connection region according to the Flip-Chip Ball-Grid-array or embedded Wafer Level BGA. A plurality of solder balls for each integrated circuit is electrically coupled to the electronic components and bonded between the respective integrated circuit and the support. The solder balls are arranged in an array, aligned along a plurality of lines parallel to a direction, wherein the plurality of lines comprises an empty line along which no solder balls are present. A conductive synchronization path is formed on the support and extends along the empty line of at least one integrated circuit, between the solder balls of the latter.