A semiconductor device has a plurality of semiconductor die disposed over a carrier. An electrical interconnect, such as a stud bump, is formed over the semiconductor die. The stud bumps are trimmed to a uniform height. A substrate includes a bump over the substrate. The electrical interconnect of the semiconductor die is bonded to the bumps of the substrate while the semiconductor die is disposed over the carrier. An underfill material is deposited between the semiconductor die and substrate. Alternatively, an encapsulant is deposited over the semiconductor die and substrate using a chase mold. The bonding of stud bumps of the semiconductor die to bumps of the substrate is performed using gang reflow or thermocompression while the semiconductor die are in reconstituted wafer form and attached to the carrier to provide a high throughput of the flipchip type interconnect to the substrate.

Semiconductor devices are described that have bump assemblies configured to furnish shock absorber functionality. In an implementation, a wafer-levelchip-scale package devices include an integrated circuit chip having an array of bump assemblies disposed over the integrated circuit chip. The array of bump assemblies comprises a plurality of first bump assemblies that include solder bumps composed at least substantially of a solder composition (i.e., solder bumps that do not include a core). The array further comprises a plurality of second bump assemblies that includes a solder bump having a core configured to furnish shock absorber functionality to the integrated circuit chip.

A driving mechanism including a first rod (103a), a second rod (104a), a first planar motor (106) moving on a plane, a center planar motor (105) moving on the plane and a moving portion (101), in which one end of the first rod is rotatably connected to the moving portion by a first rotation fulcrum (125a), the other end of the first rod is rotatably connected to the first planar motor by a second rotation fulcrum (126a), one end of the second rod is rotatably connected by a third rotation fulcrum (128a) provided on the first rod. The other end of the second rod is rotatably connected to the center planar motor by a fourth rotation fulcrum (127a), and the moving portion is moved so as to recede from the center planar motor when the first planar motor is moved near to the center planar motor.

A semiconductor device includes a substrate layer, a redistribution layer (RDL) disposed over the substrate layer, a conductive bump disposed over the RDL, and a molding disposed over the RDL and surrounding the conductive bump, wherein the molding includes a protruded portion laterally protruded from a sidewall of the substrate layer and away from the conductive bump.

An imaging module of the invention includes: an electrical cable; a solid-state image sensing device; and a flexible wiring substrate including: a device-mounted portion onto which the solid-state image sensing device is mounted; two extended portions which bend at both sides of the device-mounted portion and extend from the device-mounted portion so as to come close to each other with increasing distance from the device-mounted portion; two connection end portions extending from the two extended portions along the direction of the axis of the front end of the electrical cable on an opposite side of the device-mounted portion; and terminals which are provided on the two connection end portions and connected to the electrical cable, the flexible wiring substrate electrically connecting the solid-state image sensing device and the electrical cable.

A semiconductor device has a first build-up interconnect structure formed over a substrate. The first build-up interconnect structure includes an insulating layer and conductive layer formed over the insulating layer. A vertical interconnect structure and semiconductor die are disposed over the first build-up interconnect structure. The semiconductor die, first build-up interconnect structure, and substrate are disposed over a carrier. An encapsulant is deposited over the semiconductor die, first build-up interconnect structure, and substrate. A second build-up interconnect structure is formed over the encapsulant. The second build-up interconnect structure electrically connects to the first build-up interconnect structure through the vertical interconnect structure. The substrate provides structural support and prevents warpage during formation of the first and second build-up interconnect structures. The substrate is removed after forming the second build-up interconnect structure. A portion of the insulating layer is removed exposing the conductive layer for electrical interconnect with subsequently stacked semiconductor devices.

A device package includes a substrate having an active surface. Electrical connection bumps are deposited on the active surface and are arranged in an array having a perimeter. At least one electronic component is formed at a region of the active surface, where the region is located outside of the perimeter of the array of electrical connection bumps. When the device package is coupled with external circuitry via the electrical connection bumps, the region at which the electronic component is formed is suspended over the electronic circuitry. This region is subject to a lower stress profile than a region of the active surface circumscribed by the perimeter. Thus, stress sensitive electronic components can be located in this lower stress region of the active surface.

An interconnection structure and method disclosed for providing an interconnection structure that includes conductive features having reduced topographic variations. The interconnection structure includes a contact pad disposed over a substrate. The contact pad includes a first layer of a first conductive material and a second layer of a second conductive material over the first layer. The first conductive material and the second conductive material are made of substantially the same material and have a first average grain size and a second average grain size that is smaller than the first average grain size. The interconnection structure also includes a passivation layer covering the substrate and the contact pad, and the passivation layer has an opening exposing the contact pad.

An electronic part embedded substrate is disclosed. The electronic part embedded substrate includes a first substrate, a second substrate, an electronic part, an electrically connecting member, and a sealing member. A method of producing an electronic part embedded substrate is also disclosed. The method includes mounting an electronic part onto a first substrate, laminating a second substrate on the first substrate through an electrically connecting member; and filling a space between the first substrate and the second substrate with a sealing member to seal the electronic part.

A semiconductor package structure comprises a substrate, a die bonded to the substrate, and one or more stud bump structures connecting the die to the substrate, wherein each of the stud bump structures having a stud bump and a solder ball encapsulating the stud bump to enhance thermal dissipation and reduce high stress concentrations in the semiconductor package structure.