A semiconductor light emitting element includes a transparent substrate and a plurality of light emitting diode (LED) chips. The transparent substrate has a support surface and a second main surface disposed opposite to each other. At least some of the LED structures are disposed on the support surface and form a first main surface where light emitted from with a part of the support surface without the LED structures. Each of the LED structures includes a first electrode and a second electrode. Light emitted from at least one of the LED structures passes through the transparent substrate and emerges from the second main surface. An illumination device includes the semiconductor light emitting element and a supporting base. The semiconductor light emitting element is disposed on the supporting base, and an angle is formed between the semiconductor light emitting element and the supporting base.

Embodiments of mechanisms for forming a package are provided. The package includes a substrate and a contact pad formed on the substrate. The package also includes a conductive pillar bonded to the contact pad through solder formed between the conductive pillar and the contact pad. The solder is in direct contact with the conductive pillar.

Shielded radio-frequency (RF) module having reduced area. In some embodiments, a method for fabricating a radio-frequency module includes forming or providing a packaging substrate configured to receive a plurality of components. The method may include mounting one or more devices on the packaging substrate such that the packaging substrate includes a first area associated with mounting of each of the one or more devices. In some embodiments, the method further includes forming a plurality of shielding wirebonds on the packaging substrate to provide RF shielding functionality for one or more regions on the packaging substrate, such that the packaging substrate includes a second area associated with formation of each shielding wirebond, the mounting of each device implemented with respect to a corresponding shielding wirebond such that a portion of the first area associated with the device overlaps at least partially with a portion of the second area associated with the corresponding shielding wirebond.

A method is provided. The method includes one or more of extracting a die from an original packaged integrated circuit, modifying the extracted die, reconditioning the modified extracted die, placing the reconditioned die into a cavity of a hermetic package base, bonding a plurality of bond wires between reconditioned die pads of the reconditioned die to leads of the hermetic package base or downbonds to create an assembled hermetic package base, and sealing a hermetic package lid to the assembled hermetic package base to create a new packaged integrated circuit. Modifying the extracted die includes removing the one or more ball bonds on the one or more die pads. Reconditioning the modified extracted die includes adding a sequence of metallic layers to bare die pads of the modified extracted die. The extracted die is a fully functional semiconductor die with one or more ball bonds on one or more die pads of the extracted die.

According to one embodiment, a magnetic memory device includes a magnetic memory chip having a magnetoresistive element, a magnetic layer having first and second portions spacing out each other, the first portion covering a first main surface of the magnetic memory chip, the second portion covering a second main surface facing the first main surface of the magnetic memory chip, a circuit board on which the magnetic layer is mounted, and a bonding wire connecting between the magnetic memory chip and the circuit board in a first direction parallel to the first and second main surfaces.

A power module is provided. The power module includes a substrate, a power conversion chip that is disposed on the substrate and an insulating film that is formed on a structure in which the power conversion chip is disposed on the substrate. Additionally, the power module includes a metal mold that encases the structure that is coated with the insulating film. Additionally, the power module provides a simplified structure and improved heat dissipation performance compared to conventional power modules.

A semiconductor component includes a support having a lead integrally formed thereto. An insulated metal substrate is mounted to a surface of the support and a semiconductor chip is mounted to the insulated metal substrate. A III-N based semiconductor chip is mounted to the insulated metal substrate, where the III-N based semiconductor chip has a gate bond pad, a drain bond pad, and a source bond pad. A silicon based semiconductor chip is mounted to the III-N based semiconductor chip. In accordance with an embodiment the silicon based semiconductor chip includes a device having a gate bond pad, a drain bond pad, and a source bond pad. The drain bond pad of the III-N based semiconductor chip may be bonded to the substrate or to a lead. In accordance with another embodiment, the silicon based semiconductor chip is a diode.

Reliability of a semiconductor device is improved. A slope is provided on a side face of an interconnection trench in sectional view in an interconnection width direction of a redistribution layer. The maximum opening width of the interconnection trench in the interconnection width direction is larger than the maximum interconnection width of the redistribution layer in the interconnection width direction, and the interconnection trench is provided so as to encapsulate the redistribution layer in plan view.

A method of forming semiconductor devices includes providing a wafer having a first side and second side, electrically conductive pads at the second side, and an electrically insulative layer at the second side with openings to the pads. The first side of the wafer is background to a desired thickness and an electrically conductive layer is deposited thereon. Nickel layers are simultaneously electrolessly deposited over the electrically conductive layer and over the pads, and diffusion barrier layers are then simultaneously deposited over the nickel layers. Another method of forming semiconductor devices includes depositing backmetal (BM) layers on the electrically conductive layer including a titanium layer, a nickel layer, and/or a silver layer. The BM layers are covered with a protective coating and a nickel layer is electrolessly deposited over the pads. A diffusion barrier layer is deposited over the nickel layer over the pads, and the protective coating is removed.

A MEMS sensor device package comprises a sensor assembly comprising a sensor device and a sensor circuit communicating coupled to the sensor device, The MEMS sensor device package further comprises an assembly package housing having a top member and a bottom member attached to the top member for encapsulating the sensor assembly. A passageway fluidly coupled the sensor device to attributes outside the package housing the passageway is embedded into the package housing, wherein the top member comprising a top wall and side walls, the side walls are attached to the bottom member, and the passageway is embedded into at least one of the side walls.