A semiconductor device according to an embodiment includes: a die pad including an upper surface; a semiconductor chip provided on the upper surface, the semiconductor chip including a rectangular shape, and the semiconductor chip including an element region, and a termination region surrounding the element region; a first electrode provided on the semiconductor chip; a second electrode provided on the semiconductor chip; a first connector provided above the termination region, the first connector including a portion covering each of the four sides of the rectangular shape when viewed from above, and the first connector being electrically connected to the first electrode; and a sealing resin sealing a periphery of the semiconductor chip and the first connector.

Semiconductor module having a first substrate, a second substrate and a spacer distancing the substrates from each other, wherein the spacer is formed by at least one elastic shaped metal body.

A sensor package structure and a manufacturing method thereof are provided. The sensor package structure includes a substrate, a first solder mask layer, a convex structure, a sensing chip, and an engaging layer. The first solder mask layer is disposed on the substrate. The convex structure is disposed on the first solder mask layer. The convex structure has a first stepped surface, and the first stepped surface is higher than an upper surface of the first solder mask layer. The sensing chip is disposed above the substrate. The engaging layer is adhered between the substrate and the sensing chip and covers the convex structure, such that the convex structure and the sensing chip are not in contact with each other.

A semiconductor device includes a header, a semiconductor chip fixed to the header constituting a MOSFET, and a sealing body of insulating resin which covers the semiconductor chip, the header and the like, and further includes a drain lead contiguously formed with the header and projects from one side surface of the sealing body, and a source lead and a gate lead which project in parallel from one side surface of the sealing body, and wires which are positioned in the inside of the sealing body and connect electrodes on an upper surface of the semiconductor chip and the source lead and the gate lead, with a gate electrode pad arranged at a position from the gate lead and the source lead farther than a source electrode pad.

A semiconductor device according to an embodiment is a semiconductor device in which a semiconductor chip mounted on a chip mounting part is sealed by resin and a first member is fixed to a chip mounting surface side between a peripheral portion of the semiconductor chip and a peripheral portion of the chip mounting part. Also, the first member is sealed by the resin. Also, a length of the first part of the chip mounting part in the first direction is larger than a length of the semiconductor chip in the first direction, in a plan view.

The invention relates to a chip arrangement (10) and to a method for forming a contact connection (11) between a chip (18), in particular a power transistor or the like, and a conductor material track (14), the conductor material track being formed on a non-conductive substrate (12), the chip being arranged on the substrate or on a conductor material track (15), a silver paste (29) or a copper paste being applied to each of a chip contact surface (25) of the chip and the conductor material track (28), a contact conductor (30) being immersed into the silver paste or the copper paste on the chip contact surface and into the silver paste or the copper paste on the conductor material track, a solvent contained in the silver paste or the copper paste being at least partially vaporized by heating and the contact connection being formed by sintering the silver paste or the copper paste by means of laser energy.

A multi-chip package device includes a lead frame, a transistor chip, a metallic frame, a circuit control chip, and an encapsulation layer. The lead frame has a base seat, and a plurality of leads. The transistor chip is disposed on the base seat, and includes a plurality of source electrode pads, a gate electrode and a drain electrode. The metallic frame has a main conducting part and a conducting leg having a first conducting section and a second conducting section. The circuit control chip is disposed on the base seat and electrically connected to the transistor chip and the leads. The encapsulation layer envelops the lead frame, the transistor chip, the main conducting part, the first conducting section, and the circuit control chip to expose the second conducting section of the conducting leg.

A die stack assembly includes first and second power semiconductor device dice. The first die has a P type peripheral edge separation structure that extends from the top planar semiconductor surface of the first die all the way to the bottom planar semiconductor surface of the die, and that is doped at least in part with aluminum. The backside of the first die is mounted to the backside of the second die. A metal feature that is not covered with passivation, and that can serve as a bonding pad, is disposed on part of the peripheral edge separation structure. A metal member (for example, a bond wire or metal clip) contacts the metal feature such that an electrical connection is established from the metal member, through the metal feature, through the peripheral edge separation structure of the first die, and to an electrode of the second die.

A die stack assembly includes first and second power semiconductor device dice. The first die has a P type peripheral edge separation structure that extends from the top planar semiconductor surface of the first die all the way to the bottom planar semiconductor surface of the die, and that is doped at least in part with aluminum. The backside of the first die is mounted to the backside of the second die. A metal feature that is not covered with passivation, and that can serve as a bonding pad, is disposed on part of the peripheral edge separation structure. A metal member (for example, a bond wire or metal clip) contacts the metal feature such that an electrical connection is established from the metal member, through the metal feature, through the peripheral edge separation structure of the first die, and to an electrode of the second die.

A die stack assembly includes first and second power semiconductor device dice. The first die has a P type peripheral edge separation structure that extends from the top planar semiconductor surface of the first die all the way to the bottom planar semiconductor surface of the die, and that is doped at least in part with aluminum. The backside of the first die is mounted to the backside of the second die. A metal feature that is not covered with passivation, and that can serve as a bonding pad, is disposed on part of the peripheral edge separation structure. A metal member (for example, a bond wire or metal clip) contacts the metal feature such that an electrical connection is established from the metal member, through the metal feature, through the peripheral edge separation structure of the first die, and to an electrode of the second die.