A light emitting apparatus includes: a mount substrate; a first light emitting device mounted on the mount substrate; a light transparent member, wherein a lower surface of the light transparent member is attached to an upper surface of the first light emitting device via an adhesive material, wherein the light transparent member has a plate shape and is positioned to receive incident light emitted from the first light emitting device, and wherein a first lateral surface of the light transparent member is located laterally inward of a lateral surface of the first light emitting device; and a covering member that contains a light reflective material and covers at least the lateral surface of the light transparent member.

A system and method for preventing cracks is provided. An embodiment comprises placing crack stoppers into a connection between a semiconductor die and a substrate. The crack stoppers may be in the shape of hollow or solid cylinders and may be placed so as to prevent any cracks from propagating through the crack stoppers.

A system and method for preventing cracks is provided. An embodiment comprises placing crack stoppers into a connection between a semiconductor die and a substrate. The crack stoppers may be in the shape of hollow or solid cylinders and may be placed so as to prevent any cracks from propagating through the crack stoppers.

A display device including pads; an anisotropic conductive film on the pads; and a connection member bonded to the pads through the film, the connection member including bumps, the film includes a supporting layer including a plurality of conductive particles having a part protruded from a first and second surface of the support layer; a first adhesive layer contacting the first surface and the part of each conductive particle protruding from the first surface; and a second adhesive layer contacting the second surface and the part of each conductive particle protruding from the second surface, and wherein the first or second adhesive layer is positioned at both of a first and second region of the display device, the first region being a region in which the pads and the bumps are overlapped and the second region being a region in which the pads and the bumps are not overlapped.

A display device including pads; an anisotropic conductive film on the pads; and a connection member bonded to the pads through the film, the connection member including bumps, the film includes a supporting layer including a plurality of conductive particles having a part protruded from a first and second surface of the support layer; a first adhesive layer contacting the first surface and the part of each conductive particle protruding from the first surface; and a second adhesive layer contacting the second surface and the part of each conductive particle protruding from the second surface, and wherein the first or second adhesive layer is positioned at both of a first and second region of the display device, the first region being a region in which the pads and the bumps are overlapped and the second region being a region in which the pads and the bumps are not overlapped.

A semiconductor device has a first semiconductor die and conductive vias in the first semiconductor die. The conductive vias can be formed by extending the vias partially through a first surface of the first semiconductor die. A portion of a second surface of the first semiconductor die is removed to expose the conductive vias. A plurality of conductive pillars is formed over the first surface the first semiconductor die. The conductive pillars include an expanded base electrically connected to the conductive vias. A width of the expanded base of the conductive pillars is greater than a width of a body of the conductive pillars. A conductive layer is formed over a second surface of the first semiconductor die. The conductive layer is electrically connected to the conductive vias. A second semiconductor die is mounted to the first semiconductor die with a second conductive pillar having an expanded base.

A semiconductor device has a first semiconductor die and conductive vias in the first semiconductor die. The conductive vias can be formed by extending the vias partially through a first surface of the first semiconductor die. A portion of a second surface of the first semiconductor die is removed to expose the conductive vias. A plurality of conductive pillars is formed over the first surface the first semiconductor die. The conductive pillars include an expanded base electrically connected to the conductive vias. A width of the expanded base of the conductive pillars is greater than a width of a body of the conductive pillars. A conductive layer is formed over a second surface of the first semiconductor die. The conductive layer is electrically connected to the conductive vias. A second semiconductor die is mounted to the first semiconductor die with a second conductive pillar having an expanded base.

A semiconductor device with a ring structure surrounding a through silicon via (TSV) electrode and a method for forming the same are disclosed. The method includes receiving a substrate including a back side and a front side having a conductor thereon, forming a via hole in the substrate and exposing the conductor, forming a groove extending from the back side into the substrate and surrounding the via hole, forming a first material layer in the via hole, and forming a second material layer in the groove. The groove filled with the second material layer forms the ring structure, while the via hole filled with the first material layer forms the TSV electrode.

A semiconductor device with a ring structure surrounding a through silicon via (TSV) electrode and a method for forming the same are disclosed. The method includes receiving a substrate including a back side and a front side having a conductor thereon, forming a via hole in the substrate and exposing the conductor, forming a groove extending from the back side into the substrate and surrounding the via hole, forming a first material layer in the via hole, and forming a second material layer in the groove. The groove filled with the second material layer forms the ring structure, while the via hole filled with the first material layer forms the TSV electrode.

A fan-out wafer level package includes a semiconductor die with a redistribution layer on a sidewall of the semiconductor die. A redistribution layer positioned over the die includes an extended portion that extends along the sidewall. The semiconductor die is encapsulated in a molding compound layer. The molding compound layer is positioned between the extended portion of the redistribution layer and the sidewall of the semiconductor die. Solder contacts, for electrically connecting the semiconductor device to an electronic circuit board, are positioned on the redistribution layer. The solder contacts and the sidewall of the redistribution layer can provide electrical contact on two different locations. Accordingly, the package can be used to improve interconnectivity by providing vertical and horizontal connections.