A method of manufacturing a light emitting device includes: providing a substantially flat plate-shaped base member which in plan view includes at least one first portion having an upper surface, and a second portion surrounding the at least one first portion and having inner lateral surfaces; mounting at least one light emitting element on the at least one first portion; shifting a relative positional relationship between the at least one first portion and the second portion in an upper-lower direction to form at least one recess defined by an upper surface of the at least one first portion that serves as a bottom surface of the at least one recess and at least portions of the inner lateral surfaces of the second portion that serve as lateral surfaces of the at least one recess; and bonding the at least one first portion and the second portion with each other.

An electronic component includes one or more circuits having electrical connections coupled therewith. The electrical connections include a lead frame as well as electrical wires coupling the circuit or circuits to respective portions of the lead frame. The electrical wires may be formed as one piece with the respective portion of the lead frame without joints therebetween, e.g., by 3D printing.

According to one embodiment, there is provided a semiconductor device including a support, multiple first chips, a first sealing portion, a second chip, multiple first terminals and a second terminal. The multiple first chips are stacked on the support. The first sealing portion seals multiple first chips and has a recessed portion including a bottom surface separated from multiple first chips on a surface opposite to the support. The second chip is disposed in the recessed portion and has a function different from a function of the first chips. The multiple first terminals correspond to multiple first chips, each of multiple first terminals extending in a stacking direction from a surface of the first chip opposite to the support and penetrating the first sealing portion. The second terminal is disposed on a surface of the second chip opposite to the support.

A re-distribution layer structure is adapted to be disposed on a substrate having a pad and a protective layer which has a first opening exposing a part of the pad. The re-distribution layer structure includes a first and a second patterned insulating layers and a re-distribution layer. The first patterned insulating layer is disposed on the protective layer and includes at least one protrusion and a second opening corresponding to the first opening. The re-distribution layer is disposed on the first patterned insulating layer and includes a pad portion and a wire portion. The pad portion is located on the first patterned insulating layer. The wire portion includes a body and at least one trench caved in the body. The body extends from the pad portion to the pad exposed by the first and the second openings. The body covers the protrusion, and the at least one protrusion extends into the at least one trench. The second patterned insulating layer covers the wire portion and exposes a part of the pad portion. A manufacturing method of re-distribution layer structure is further provided.

A semiconductor device has a first semiconductor die stacked over a second semiconductor die which is mounted to a temporary carrier. A plurality of bumps is formed over an active surface of the first semiconductor die around a perimeter of the second semiconductor die. An encapsulant is deposited over the first and second semiconductor die and carrier. A plurality of conductive vias is formed through the encapsulant around the first and second semiconductor die. A portion of the encapsulant and a portion of a back surface of the first and second semiconductor die is removed. An interconnect structure is formed over the encapsulant and the back surface of the first or second semiconductor die. The interconnect structure is electrically connected to the conductive vias. The carrier is removed. A heat sink or shielding layer can be formed over the encapsulant and first semiconductor die.

An apparatus relating generally to a substrate is disclosed. In such an apparatus, a first bond via array has first wires extending from a surface of the substrate. A second bond via array has second wires extending from the surface of the substrate. The first bond via array is disposed at least partially within the second bond via array. The first wires of the first bond via array are of a first height. The second wires of the second bond via array are of a second height greater than the first height for coupling of at least one die to the first bond via array at least partially disposed within the second bond via array.

A method of improving electrical interconnections between two electrical elements is made available by providing a meta-material overlay in conjunction with the electrical interconnection. The meta-material overlay is designed to make the electrical signal propagating via the electrical interconnection to act as though the permittivity and permeability of the dielectric medium within which the electrical interconnection is formed are different than the real component permittivity and permeability of the dielectric medium surrounding the electrical interconnection. In some instances the permittivity and permeability resulting from the meta-material cause the signal to propagate as if the permittivity and permeability have negative values. Accordingly the method provides for electrical interconnections possessing enhanced control and stability of impedance, reduced noise, and reduced loss. Alternative embodiments of the meta-material overlay provide, the enhancements for conventional discrete wire bonds whilst also facilitating single integrated designs compatible with tape implementation.

An electronic component includes one or more circuits having electrical connections coupled therewith. The electrical connections include a lead frame as well as electrical wires coupling the circuit or circuits to respective portions of the lead frame. The electrical wires may be formed as one piece with the respective portion of the lead frame without joints therebetween, e.g., by 3D printing.

A semiconductor device includes an insulated circuit board including a circuit pattern, a semiconductor chip on the circuit pattern, a wire connected to the semiconductor chip, an external connection terminal including a leg portion extending in a direction perpendicular to a front surface of the circuit pattern and a terminal portion electrically connected to the leg portion, and a case including a frame portion which surrounds an insulated circuit board and a beam portion bonded to an external connection terminal and overlapping at least a part of a wire in a plan view of the semiconductor device, and a sealing member with which the case is filled, which seals a front surface of the insulated circuit board, a semiconductor chip, the wire, and a back surface of the beam portion, and which is exposed in the plan view from a gap between a leg portion and the beam portion.

A new method, system and apparatus for mounting mechanically, thermally and electrically light emitting diode (LED), crystals, arrays or packages. The above provides an LED assembly having reduced number of components and costs, superior heat dissipation, mechanical properties and a compact structure. The use of a grid or mesh allows for more efficient and inexpensive removal of heat from one or more LEDs within an LED fixture.