A transistor device is disclosed. The transistor device includes: a semiconductor body; a source conductor on top of the semiconductor body; a source clip on top of the source conductor and electrically connected to the source conductor; a first active device region arranged in the semiconductor body, covered by the source conductor and the source clip, and including at least one device cell; and a second active device region arranged in the semiconductor body, covered by regions of the source conductor that are not covered by the source clip, and including at least one device cell. The first active device region has a first area specific on-resistance and the second active device region has a second area specific on-resistance, the second area specific on-resistance being greater than the first area specific on-resistance.

A half-bridge power device includes a module substrate, the upper surface of which includes a first half-bridge area, a second half-bridge area, a first half-bridge lead-out area, and a second half-bridge lead-out area, which are separate, the first and second half-bridge lead-out areas being located at the ends of the module substrate. The first and second half-bridge power chips are connected to the first half-bridge area and the second half-bridge area, respectively. The first, second, and third power connector terminals are connected to the first and second half-bridge areas, and the first and second half-bridge power chips to form a power loop.

A semiconductor device comprises a first chip pad, a power semiconductor chip arranged on the first chip pad and comprising at least a first and a second power electrode, and a clip connected to the first power electrode. In this case, an integral part of the clip forms a shunt resistor and a first contact finger of the shunt resistor is embodied integrally with the clip.

A method of manufacturing a semiconductor device that includes an insulated circuit board having a conductive pattern, a first semiconductor chip with a rectangular shape connected through a first joining material to the conductive pattern, a second semiconductor chip with a rectangular shape disposed on the conductive pattern separated from the first semiconductor chip and connected through a second joining material to the conductive pattern, a terminal disposed above the semiconductor chips, respectively connected to the first and second semiconductor chips through third and fourth joining materials, the terminal having a through-hole above a place between the first and second semiconductor chips, the method including a positioning step in which the first and second semiconductor chips are respectively positioned at at least three positioning places, and at least one of the positioning places is positioned with a positioning member inserted into the through-hole.

A semiconductor package includes: a substrate having a metallic surface; a semiconductor die metallurgically bonded to the metallic surface of the substrate by a first solder joint; and a solder wetting structure metallurgically welded to the metallic surface of the substrate outside a perimeter of the semiconductor die and adjacent to one or more side faces of the semiconductor die. Excess solder squeezed out from under the semiconductor die is metallurgically bonded to the solder wetting structure. Methods of producing the semiconductor package and solder wetting structure are also described.

A semiconductor device includes: first and second semiconductor elements each having two electrodes respectively disposed on two surfaces; two first terminals respectively connected to the two electrodes of the first semiconductor element and arranged side by side in one direction; two second terminals respectively connected to the two electrodes of the second semiconductor element, and arranged side by side in the one direction to be adjacent to the two first terminals; and a sealing resin portion covering the first and second semiconductor elements and the first and second terminals in a state where facing surfaces of the first and second terminals are exposed from the sealing resin portion. The facing surfaces of the two first terminals have different area ratios, the facing surfaces of the two second terminals have different area ratios, and one of the first terminals is arranged adjacent to both the two second terminals.

A semiconductor device includes a semiconductor element; a first lead including a die pad portion and a first terminal portion, and a sealing resin. A first lead reverse surface is exposed from a second resin surface. The first terminal portion includes a first portion extending outward from a third resin surface to a first side in an x direction, a second portion located on a first side in a z direction relative to the first portion and used for mounting, and a third portion interposed between the first portion and the second portion. The second portion overlaps with the sealing resin as viewed in the z direction.

A semiconductor device includes: a semiconductor element; a first lead including a die pad portion and a first terminal portion; and a sealing resin. A first lead reverse surface is exposed from a second resin surface and spaced apart from a third resin surface in a first direction. The first terminal portion includes a first portion and a second portion. Only one set of the first portion passes through the third resin surface. The first portion is spaced apart from the second resin surface in a z direction. The second portion is located on a first side in the z direction relative to the first portion and used for mounting.

A method of manufacturing a semiconductor device that includes an insulated circuit board having a conductive pattern, a first semiconductor chip with a rectangular shape connected through a first joining material to the conductive pattern, a second semiconductor chip with a rectangular shape disposed on the conductive pattern separated from the first semiconductor chip and connected through a second joining material to the conductive pattern, a terminal disposed above the semiconductor chips, respectively connected to the first and second semiconductor chips through third and fourth joining materials, the terminal having a through-hole above a place between the first and second semiconductor chips, the method including a positioning step in which the first and second semiconductor chips are respectively positioned at at least three positioning places, and at least one of the positioning places is positioned with a positioning member inserted into the through-hole.

A semiconductor device has a plurality of small-sized semiconductor chips disposed between an insulated circuit board having a conductive pattern and a terminal. The semiconductor device exhibits a high accuracy in positioning the semiconductor chips. The semiconductor device includes an insulated circuit board having a conductive pattern, a first semiconductor chip with a rectangular shape connected to the conductive pattern through a first joining material, a second semiconductor chip with a rectangular shape, disposed on the conductive pattern separated from the first semiconductor chip and connected to the conductive pattern through a second joining material, and a terminal disposed above the first semiconductor chip and the second semiconductor chip, connected to the first semiconductor chip through a third joining material, and connected to the second semiconductor chip through a fourth joining material. The terminal has a through-hole above a place between the first semiconductor chip and the second semiconductor chip.