A semiconductor device includes a board having a solder resist layer with first and second openings on a first surface, and a first electrode on the first surface, a portion thereof exposed in the first opening and electrically connected to the board. A second electrode is located on the first surface having a portion exposed in the second opening and electrically connected to the board. A portion of the second electrode is covered by the solder resist layer. A first solder bump is on the first electrode and covers a side surface. A second solder bump is on the second electrode. A semiconductor chip has a first region and a second region facing the first surface. A third electrode is in the first region and electrically connected to the first solder bump. A fourth electrode is in the second region and electrically connected to the second solder bump.

A semiconductor device includes a semiconductor substrate having a main surface; a first coil formed on the main surface; a first insulating film formed over the first coil and having a first main surface; a second insulating film formed on the first main surface of the first insulating film and having a second main surface; and a second coil formed on the second main surface of the second insulating film, wherein the first main surface of the first insulating film has a first area on which the second insulating film is formed, and has a second area without the first area in a plan view, and wherein the second insulating film is surrounded with the second area in the plane view.

A sensor chip package assembly and an electronic device having the sensor chip package assembly are disclosed, where the sensor chip package assembly includes: a metal substrate (100) which has a bonding pad region (11) and a placement region (12), the bonding pad region having a plurality of metal bonding pads (13); a sensor chip (200) which is located on an upper surface of the metal substrate, and the sensor chip having a plurality of sensor chip bonding pads (21); an electrical connection assembly (300) which electrically connects a metal bonding pad and a sensor chip bonding pad; and a packaging material cover (400) which covers the metal substrate, the sensor chip and the electrical connection assembly, where any two adjacent metal bonding pads are spaced in an insulated manner by the packaging material cover.

The present invention relates to a camera module in which a thin camera module can be realized at a low cost and an electronic device. The camera module includes a lens unit that stores a lens that condenses light on a light receiving surface of an image sensor; a rigid substrate on which the image sensor is disposed; and a flexible substrate electrically connected with the rigid substrate, wherein in the case where the light receiving surface of the image sensor locates at the top, the lens unit, the flexible substrate, and the rigid substrate are disposed in this order from the top.

Electrode pads disposed on a first surface of a semiconductor element include a first pad located close to a corner and a second pad located apart from the corner compared with the first pad. A first wire connected to the first pad has a smaller Young's modulus than a second wire connected to the second pad. A thickness of an intermetallic compound layer formed by the first wire and the first pad is larger than a thickness of an intermetallic compound layer formed by the second wire and the second pad.

A semiconductor device includes: a wiring board, a chip stack provided above the wiring board and including a first semiconductor chip; a second semiconductor chip provided between the wiring board and the first semiconductor chip; a first adhesive layer provided between the first semiconductor chip and the second semiconductor chip and on the second semiconductor chip; and a sealing insulation layer including a first part and a second part, the first part covering the chip stack, and the second part extending between the wiring board and the first semiconductor chip.

A semiconductor package includes a pad and leads having a planar profile shaped from a planar base metal, a semiconductor die attached to the pad, a wire bond extending from the semiconductor die to a respective lead, and mold compound covering the semiconductor die, the wire bond, and a first portion of the respective lead, wherein a second portion of the respective lead extends beyond the mold compound. A shape of the respective lead within the planar profile includes a notch indented relative to a first elongated side of the shape of the respective lead and a protrusion protruding outwardly relative to a second elongated side of the shape of the respective lead. The notch and the protrusion are each partially covered by the mold compound and partially outside the mold compound.

Semiconductor packages and methods for forming thereof are disclosed. The semiconductor package includes a package substrate having a die attach region with a die attached thereto. A protective cover is disposed over a sensor region of the die and attached to the die by a cover adhesive. The cover adhesive may serve as a standoff structure to support the protective cover. The standoff structure may be configured to form multiple cavities below the protective cover to reduce thermal stress on the protective cover. An encapsulant is disposed to cover the package substrate while leaving the top package surface exposed.

Examples herein relate to optoelectronic systems or modules. In particular, implementations herein relate to an optoelectronic module or system that includes a substrate having opposing first and second sides and an optoelectronic component having opposing first and second sides flip chip assembled to the substrate. The optoelectronic component is configured to emit at least one optical signal to the substrate, receive at least one optical signal from the substrate, or both. The optoelectronic system further includes an underfill exclusion structure configured to prevent underfill material dispensed between the optoelectronic component and the substrate from flowing into an optical area or path of the at least one optical signal transmitted between the optoelectronic component and the substrate. The underfill exclusion structure is spaced apart from at least one of the optoelectronic component or the substrate.

A semiconductor package includes a first semiconductor chip including a first surface and a second surface which face each other, an alignment pattern formed on the first surface, a first redistribution layer arranged on the first surface of the first semiconductor chip, a second redistribution layer arranged on the second surface of the first semiconductor chip, and electrically connected with the semiconductor chip, and a first dielectric layer including the alignment pattern between the first redistribution layer and the semiconductor chip, the alignment pattern overlapping the first surface of the first semiconductor chip.