Abstract: The present invention provides a semiconductor device with an improved yield ratio and reduced height and manufacturing cost; and a method of manufacturing the semiconductor device. According to an aspect of the present invention, there is provided a semiconductor device including a substrate, a semiconductor element that is flip-chip connected to the substrate, and a molding portion that seals the semiconductor element. The side surfaces of the semiconductor element are enclosed by the molding portion. An upper surface of the semiconductor element is not enclosed by the molding portion. Damage to the side surfaces of the semiconductor element caused by an external impact when the semiconductor device is stored is minimized, because the molding portion protects the side surfaces of the semiconductor element. Accordingly, the yield ratio of the semiconductor device is improved.

Abstract: A carrier for a stacked type semiconductor device includes a lower carrier having a first accommodating portion that accommodates a first semiconductor device, and an upper carrier having a second accommodating portion that accommodates a second semiconductor device stacked on the first semiconductor device so as to be placed in position on the first semiconductor device. It is thus possible to eliminate an additional device used for stacking the semiconductor device, and thereby reduce the cost.

Abstract: A carrier for a stacked type semiconductor device includes a lower carrier having a first accommodating portion that accommodates a first semiconductor device, and an upper carrier having a second accommodating portion that accommodates a second semiconductor device stacked on the first semiconductor device so as to be placed in position on the first semiconductor device. It is thus possible to eliminate an additional device used for stacking the semiconductor device, and thereby reduce the cost.

Abstract: In a camera module of a so-called multi-chip type, an imaging device and a semiconductor element for processing are mounted. The semiconductor element is encapsulated by a mold resin. Protruding parts are formed by the mold resin on a mounting surface of the mold resin. A metal film forming a pattern wiring is formed on the mounting surface of the mold resin. The metal film is also formed on the protruding parts so as to constitute external connection terminals together with the protruding parts. Electrodes of the semiconductor element are electrically connected to the pattern wiring. The protruding parts include first protruding parts positioned around the semiconductor element and second protruding parts formed in a mounting area of the semiconductor element on the mounting surface.

Abstract: In a camera module of a so-called multi-chip type, an imaging device and a semiconductor element for processing are mounted. The semiconductor element is encapsulated by a mold resin. Protruding parts are formed by the mold resin on a mounting surface of the mold resin. A metal film forming a pattern wiring is formed on the mounting surface of the mold resin. The metal film is also formed on the protruding parts so as to constitute external connection terminals together with the protruding parts. Electrodes of the semiconductor element are electrically connected to the pattern wiring. The protruding parts include first protruding parts positioned around the semiconductor element and second protruding parts formed in a mounting area of the semiconductor element on the mounting surface.

Abstract: The present invention provides a semiconductor device that includes: stacked semiconductor chips, each semiconductor chip including a semiconductor substrate and a first insulating layer that is provided on side faces of the semiconductor substrate and has concavities formed on side faces thereof; first metal layers that are provided in center portions of inner side faces of the concavities; and second metal layers that are provided in the concavities and are connected to the first metal layers formed on each semiconductor chip. The present invention also provides a method of manufacturing the semiconductor device.

Abstract: The present invention provides a semiconductor device, a fabrication method therefor, and a film fabrication method, the semiconductor device including a first substrate (e.g., a semiconductor chip), an anisotropic conductive film that is provided on the first substrate and has a wiring pattern having at least a portion providing conduction through the anisotropic conductive film, and a second substrate (semiconductor chip) provided on the anisotropic conductive film and coupled to the first substrate via the portion providing conduction through the anisotropic conductive film. According to the present invention, it is possible to provide a semiconductor device, a fabrication method therefor, and a film fabrication method, by which production costs can be reduced in electrically coupling different positions in upper and lower substrates.

Abstract: In a camera module of a so-called multi-chip type, an imaging device and a semiconductor element for processing are mounted. The semiconductor element is encapsulated by a mold resin. Protruding parts are formed by the mold resin on a mounting surface of the mold resin. A metal film forming a pattern wiring is formed on the mounting surface of the mold resin. The metal film is also formed on the protruding parts so as to constitute external connection terminals together with the protruding parts. Electrodes of the semiconductor element are electrically connected to the pattern wiring. The protruding parts include first protruding parts positioned around the semiconductor element and second protruding parts formed in a mounting area of the semiconductor element on the mounting surface.

Abstract: The present invention provides a semiconductor device and a fabrication method therefor, the semiconductor device including a first semiconductor chip (20) disposed on a substrate (10), a first sealing resin (26) sealing the first semiconductor chip (20), a built-in semiconductor device (30) disposed on the first sealing resin (26), and a second sealing resin (36) sealing the first sealing resin (26) and the built-in semiconductor device (30) and covering a side surface (S) of the substrate (10). According to an aspect of the present invention, it is possible to provide a high-quality semiconductor device and a fabrication method therefor, in which downsizing and cost reduction can be realized.

Abstract: A device including a chip, and a resin package sealing the chip, the resin package having resin projections located on a mount-side surface of the resin package. Metallic films are respectively provided to the resin projections. Connecting parts electrically connect electrode pads of the chip and the metallic film.

Abstract: A carrier for a stacked-type semiconductor device includes an accommodating section for accommodating stacked semiconductor devices, guide portions guiding the stacked semiconductor devices, and grooves through which a fluid may flow to the accommodating section and to sides of the stacked semiconductor devices. These grooves facilitate the flow of gas or liquid on the sides of the accommodating sections, and it is thus expected that the flow of hot wind during the reflow process and cleaning liquid during the cleaning process can be facilitated. This improves the production yield and the cleaning effects. Holes for connecting the accommodating section to the outside may be provided at corners of the accommodating section. Gas may be guided from the lower side of the accommodating section, so that heat can be efficiently applied to the semiconductor devices and bonding failures therebetween can be reduced.

Abstract: A camera module includes a module structure constituted by a lens unit to which an image pickup lens is attached and a package to which an imaging element is attached so as to be opposite to the image pickup lens. An optical filter is arranged between the imaging element and the image pickup lens. A portion of a flat surface of the optical filter is fixed to a filter fixing portion via an adhesive. The optical filter is adhered to the filter fixing portion in a state in which an end portion formed by a side surface of the optical filter and the flat surface is in noncontact with the filter fixing portion or the adhesive. Minute particles generated from a cut surface of the optical filter fall outside the filer fixing portion.

Abstract: A semiconductor device of a stacked type includes a semiconductor chip (1) that is mounted on a substrate (4), a first sealing resin (12) that seals the semiconductor chip (1), a built-in semiconductor device (9) that is placed on the first sealing resin (12), and a second sealing resin (13) that is formed on the substrate (4) and seals the semiconductor chip (1) and the built-in semiconductor device (9). In this semiconductor device, the semiconductor chip (1) and the built-in semiconductor device (9) are electrically connected to the substrate by bonding wires (3).

Abstract: A stacked type semiconductor device includes semiconductor devices, interposers by which the semiconductor devices are stacked, the interposers having electrodes provided on sides thereof, and a connection substrate connecting the electrodes together. The electrodes provided on the sides of the interposers may be connected to the connection substrate by one of an electrically conductive adhesive or an anisotropically conductive film.

Abstract: A carrier structure for fabricating a stacked-type semiconductor device includes: a lower carrier that has laminated thin plates and has first openings for mounting first semiconductor packages thereon; and an upper carrier having second openings for mounting second semiconductor packages on the first semiconductor packages. The lower carrier composed of the laminated thin plates realizes an even plate thickness and reduces warps because stress is distributed to the thin plates. This results in an improved production yield. A pattern of the openings in the thin plates of the lower carrier may be formed by etching or electric discharging. The openings thus formed have reduced warps and burrs.

Abstract: A carrier for a stacked type semiconductor device includes a lower carrier having a first accommodating portion that accommodates a first semiconductor device, and an upper carrier having a second accommodating portion that accommodates a second semiconductor device stacked on the first semiconductor device so as to be placed in position on the first semiconductor device. It is thus possible to eliminate an additional device used for stacking the semiconductor device, and thereby reduce the cost.

Abstract: A method of fabricating a semiconductor device includes the steps of providing a heat-resistant sheet on an interposer so as to cover electrode terminals provided on the interposer, and sealing a semiconductor chip on the interposer sandwiched between molds with a sealing material. The electrode terminals are covered by the heat-resistant resin for protection, and the semiconductor chip is then sealed with resin. It is thus possible to avoid the problem in which contaminations adhere to the electrode terminals. This makes it possible to prevent the occurrence of resin burrs on the interposer and contamination of the electrode pads and to improve the production yield.

Abstract: A method includes a resin sealing step of placing, in a cavity 28 of a mold 20, a substrate 16 to which semiconductor elements 11 on which bumps 12 are arranged, a resin sealing step of supplying resin 35 to positions of the bumps 12 so that a resin layer 13 sealing the bumps 12 is formed, a protruding electrode exposing step of exposing at least ends of the bumps 12 sealed by the resin layer 13 so that ends of the bumps 12 are exposed from the resin layer 13, and a separating step of cutting the substrate 16 together with the resin layer 13 so that the semiconductor elements 11 are separated from each other.

Abstract: A device including a chip, and a resin package sealing the chip, the resin package having resin projections located on a mount-side surface of the resin package. Metallic films are respectively provided to the resin projections. Connecting parts electrically connect electrode pads of the chip and the metallic film.

Abstract: In a camera module of a so-called multi-chip type, an imaging device and a semiconductor element for processing are mounted. The semiconductor element is encapsulated by a mold resin. Protruding parts are formed by the mold resin on a mounting surface of the mold resin. A metal film forming a pattern wiring is formed on the mounting surface of the mold resin. The metal film is also formed on the protruding parts so as to constitute external connection terminals together with the protruding parts. Electrodes of the semiconductor element are electrically connected to the pattern wiring. The protruding parts include first protruding parts positioned around the semiconductor element and second protruding parts formed in a mounting area of the semiconductor element on the mounting surface.