Abstract: A non-leaded resin-sealed semiconductor device is manufactured by the steps of providing a conductive flat substrate (metal plate) of copper plate or the like, fixing semiconductor elements respectively to predetermined positions on the principal surface of the substrate by an insulating adhesive, electrically connecting electrodes on the surfaces of the semiconductor elements with predetermined partition parts of the substrate separate from the semiconductor elements by conductive wires, forming an insulating resin layer on the principal surface of the substrate to cover the semiconductor elements and wires, selectively removing the substrate from the rear of said substrate to form electrically independent partition parts whereof at least some are external electrode terminals, and selectively removing said resin layer to fragment the device into regions containing the semiconductor elements and the plural partition parts around the semiconductor elements.

Abstract: The present invention enhances the reliability of a semiconductor device. The semiconductor device includes a package substrate having a dry resist film which covers some conductive portions out of a plurality of conductive portions formed on a main surface and a back surface and is formed of a film, a semiconductor chip which is mounted over the package substrate, conductive wires which electrically connect the semiconductor chip with the package substrate, a die-bonding film which is arranged between the main surface of the package substrate and the semiconductor chip, a plurality of solder bumps which are formed on the back surface of the package substrate, and a sealing body which is made of resin.

Abstract: A semiconductor device manufacturing method capable of improving the semiconductor device manufacturing yield is disclosed. Semiconductor chips are mounted respectively over semiconductor device regions of a matrix wiring substrate having plural semiconductor device regions, followed by wire bonding, and thereafter sealing resin is formed at a time onto the semiconductor device regions. Thereafter, target marks for dicing are formed on an upper surface of the sealing resin on the basis of target marks pre-formed on an upper surface of the wiring substrate. Then, half-dicing is performed from the upper surface side of the sealing resin 5a on the basis of the target marks for dicing to form grooves whose bottoms reach the wiring substrate. Subsequently, solder balls are connected to a lower surface of the wiring substrate and dicing is performed from a lower surface side of the wiring substrate for division into individual semiconductor devices.

Abstract: The present invention enhances the reliability of a semiconductor device. The semiconductor device includes a package substrate having a dry resist film which covers some conductive portions out of a plurality of conductive portions formed on a main surface and a back surface and is formed of a film, a semiconductor chip which is mounted over the package substrate, conductive wires which electrically connect the semiconductor chip with the package substrate, a die-bonding film which is arranged between the main surface of the package substrate and the semiconductor chip, a plurality of solder bumps which are formed on the back surface of the package substrate, and a sealing body which is made of resin.

Abstract: A non-leaded resin-sealed semiconductor device is manufactured by the steps of providing a metal substrate having a front surface, a rear surface, a chip fixing partition part, partition parts arranged around the chip fixing partition part, and grooves defined between the partition parts; providing a semiconductor chip having a front surface, a rear surface, electrodes formed on the front surface; fixing the semiconductor chip on the chip fixing partition part of the front surface of the metal substrate; electrically connecting the electrodes of the semiconductor chip with the front surface of the partition parts of the metal substrate by conductive wires, respectively; and forming a resin body which seals the semiconductor chip, the conductive wires, and the front surface of the partition parts of the metal substrate.

Abstract: A semiconductor device manufacturing method capable of improving the semiconductor device manufacturing yield is disclosed. Semiconductor chips are mounted respectively over semiconductor device regions of a matrix wiring substrate having plural semiconductor device regions, followed by wire bonding, and thereafter sealing resin is formed at a time onto the semiconductor device regions. Thereafter, target marks for dicing are formed on an upper surface of the sealing resin on the basis of target marks pre-formed on an upper surface of the wiring substrate. Then, half-dicing is performed from the upper surface side of the sealing resin 5a on the basis of the target marks for dicing to form grooves whose bottoms reach the wiring substrate. Subsequently, solder balls are connected to a lower surface of the wiring substrate and dicing is performed from a lower surface side of the wiring substrate for division into individual semiconductor devices.

Abstract: A semiconductor device which permits reduction in the number of pins and in size thereof is provided.

Abstract: A method of manufacturing a thin, small-sized, inexpensive, non-leaded, resin-sealed type semiconductor device is disclosed. A flexible tape having plural terminals peelably through a first adhesive in a product forming portion formed on a main surface of the tape is provided, a semiconductor element is fixed to the main surface of the tape peelably through a second adhesive, electrodes formed on the semiconductor element and the terminals are connected together through conductive wires, an insulating resin layer is formed in an area including the semiconductor element and the wires on the main surface of the tape to cover the semiconductor element and the wires, and the tape on a back surface of the insulating resin layer is peeled, allowing the terminals to be exposed to the back surface of the insulating resin layer. Exposed surfaces of the terminals are each formed by a gold layer.

Abstract: A semiconductor device manufacturing method capable of improving the semiconductor device manufacturing yield is disclosed. Semiconductor chips are mounted respectively over semiconductor device regions of a matrix wiring substrate having plural semiconductor device regions, followed by wire bonding, and thereafter sealing resin is formed at a time onto the semiconductor device regions. Thereafter, target marks for dicing are formed on an upper surface of the sealing resin on the basis of target marks pre-formed on an upper surface of the wiring substrate. Then, half-dicing is performed from the upper surface side of the sealing resin 5a on the basis of the target marks for dicing to form grooves whose bottoms reach the wiring substrate. Subsequently, solder balls are connected to a lower surface of the wiring substrate and dicing is performed from a lower surface side of the wiring substrate for division into individual semiconductor devices.

Abstract: Peeling of the core material in the wiring substrate of a semiconductor device is suppressed. The multi-chip substrate is divided so that the foldout direction of fiber and the dividing direction of a substrate in each of first core material of two sheets of a multi-chip substrate may accomplish an acute angle, and fiber is exposed to the end face formed of this division. When the foldout direction of each fiber of the first core material of two sheets and the extending direction of the end face accomplish an acute angle, fiber woven into first core material can be made fine. Exposure of the portion of resin comparatively weak to stress can be lessened. As a result, peeling of resin in a cutting plane can be suppressed. Since the foldout direction and the dividing direction of fiber are an acute angle, progress of peeling can be suppressed.

Abstract: Wire connection failure in semiconductor device is prevented. A semiconductor device has a package substrate having, at the periphery of the main surface thereof, a plurality of bonding leads disposed in a row, a semiconductor chip mounted inside of the row of the bonding leads on the main surface of the package substrate, wires for connecting pads of the semiconductor chip and the bonding leads of the substrate, a sealing body for resin sealing the semiconductor chip and the plurality of wires, and a plurality of solder bumps disposed on the back surface of the package substrate. The top of the loop of each of the wires is disposed outside the wire connecting portion so that the wire length wire can be increased in the connection between the bonding leads and the pads of the semiconductor chip. As a result, the wires have a stable loop shape and a wire connection failure can be prevented.

Abstract: A semiconductor device which permits reduction in the number of pins and in size thereof is provided.

Abstract: A semiconductor device which permits reduction in the number of pins and in size thereof is provided.

Abstract: The present invention enhances the reliability of a semiconductor device. The semiconductor device includes a package substrate having a dry resist film which covers some conductive portions out of a plurality of conductive portions formed on a main surface and a back surface and is formed of a film, a semiconductor chip which is mounted over the package substrate, conductive wires which electrically connect the semiconductor chip with the package substrate, a die-bonding film which is arranged between the main surface of the package substrate and the semiconductor chip, a plurality of solder bumps which are formed on the back surface of the package substrate, and a sealing body which is made of resin.

Abstract: A semiconductor device includes a semiconductor chip, a plurality of bonding pads which are formed on a main surface of the semiconductor chip and include first power source bonding pads, second power source bonding pads and a plurality of signal bonding pads, a plurality of leads which are arranged around the semiconductor chip and include first power source leads and a plurality of signal leads, a plurality of bonding wires which include first bonding wires for connecting the first power source bonding pads with the first power source leads, second bonding wires for connecting the first bonding pads with second bonding pads and third bonding wires for connecting the plurality of signal bonding pads with the plurality of signal leads, and a sealing body which seals the semiconductor chip, the plurality of bonding wires and some of the plurality of leads.

Abstract: The miniaturization of a semiconductor device is aimed at. A package substrate have a plurality of terminals formed on the main surface, a plurality of lands formed on the back surface, through holes which are formed by laser beam machining and have been arranged at the upper part of each of the plurality of lands, and plating films which are arranged in the through hole and connect the land with the terminal electrically, a semiconductor chip which is mounted on the main surface of the package substrate, a conductive wire which connects the pad of the semiconductor chip and the package substrate, and a plurality of solder bumps formed in the lands of the package substrate. Since the through hole is formed by laser beam machining, the opening of the through hole is small. It becomes possible to arrange a solder bump directly under the through hole, and miniaturization of CSP 7 (semiconductor device) can be realized.

Abstract: A first solder resist section and a second solder resist section are formed over an upper surface of a wiring board. A semiconductor chip is bonded onto the first solder resist section via an adhesive interposed therebetween. Electrodes of the semiconductor chip are respectively electrically connected to connecting terminals exposed through openings of the second solder resist section via bonding wires. An encapsulating resin is formed over the upper surface of the wiring board so as to cover the semiconductor chip and the bonding wires. A plane dimension of the first solder resist section is smaller than that of the semiconductor chip, and the encapsulating resin is filled even below an outer peripheral portion of a back surface of the semiconductor chip.

Abstract: A semiconductor device includes a semiconductor chip, a plurality of bonding pads which are formed on a main surface of the semiconductor chip and include first power source bonding pads, second power source bonding pads and a plurality of signal bonding pads, a plurality of leads which are arranged around the semiconductor chip and include first power source leads and a plurality of signal leads, a plurality of bonding wires which include first bonding wires for connecting the first power source bonding pads with the first power source leads, second bonding wires for connecting the first bonding pads with second bonding pads and third bonding wires for connecting the plurality of signal bonding pads with the plurality of signal leads, and a sealing body which seals the semiconductor chip, the plurality of bonding wires and some of the plurality of leads.

Abstract: There are constituted by a tab (1b) on which a semiconductor chip (2) is mounted, a sealing portion (3) formed by resin-sealing the semiconductor chip (2), a plurality of leads (1a) each having a mounted surface (1d) exposed to a peripheral portion of a rear surface (3a) of the sealing portion (3) and a sealing-portion forming surface (1g) disposed on an opposite side thereto, and a wire (4) for connecting a pad (2a) of the semiconductor chip (2) and a lead (1a), wherein the length (M) between inner ends (1h) of the sealing-portion forming surfaces (1g) of the leads (1a) disposed so as to oppose to each other is formed to be larger than the length (L) between inner ends (1h) of the mounted surfaces (1d). Thereby, a chip mounting region surrounded by the inner end (1h) of the sealing-portion forming surface (1g) of each lead (1a) can be expanded and the size of the mountable chip is increased.

Abstract: A semiconductor device which permits reduction in the number of pins and in size thereof is provided.