A semiconductor module includes a laminated substrate including an insulating board and a plurality of circuit boards that are arranged on an upper face of the insulating board, the plurality of circuit boards including first and second circuit boards, a semiconductor element disposed on the first circuit board and including, on an upper face of the semiconductor element, a main electrode, a gate pad, and a gate runner electrically connected to the gate pad, and a first wiring member electrically connecting the main electrode to the second circuit board. The gate runner extends so as to divide the main electrode into a plurality of electrodes including a first main electrode at a first side and a second main electrode at a second side, and the first wiring member is arranged to cross over the gate runner.

A power module includes a mount layer, a control layer, and a drive layer that are formed on an electrically insulative substrate and multiple power semiconductor elements mounted on the mount layer in one direction and each including a first drive electrode connected to the mount layer, a second drive electrode connected to the drive layer, and a control electrode connected to the control layer. A control terminal is connected to the control layer and a detection terminal is connected to the drive layer. At least one of the control layer and the drive layer includes a detour portion that detours to reduce a difference between the power semiconductor elements in a sum of a length of a first conductive path between the control electrode and the control terminal and a length of a second conductive path between the second drive electrode and the detection terminal.

A power module includes a mount layer, a control layer, and a drive layer that are formed on an electrically insulative substrate and multiple power semiconductor elements mounted on the mount layer in one direction and each including a first drive electrode connected to the mount layer, a second drive electrode connected to the drive layer, and a control electrode connected to the control layer. A control terminal is connected to the control layer and a detection terminal is connected to the drive layer. At least one of the control layer and the drive layer includes a detour portion that detours to reduce a difference between the power semiconductor elements in a sum of a length of a first conductive path between the control electrode and the control terminal and a length of a second conductive path between the second drive electrode and the detection terminal.

A connecting strip of conductive elastic material having an arched shape having a concave side and a convex side. The connecting strip is fixed at the ends to a support carrying a die with the convex side facing the support. During bonding, the connecting strip undergoes elastic deformation and presses against the die, thus electrically connecting the at least one die to the support.

A semiconductor device provided with first and second semiconductor element each having an obverse and a reverse surface with a drain electrode, source electrode and gate electrode provided on the obverse surface. The semiconductor device is also provided with a control element electrically connected to the gate electrodes of the respective semiconductor elements, and with a plurality of leads, which include a first lead carrying the first semiconductor element, a second lead carrying the second semiconductor element, and a third lead carrying the control element. The first and second leads overlap with each other as viewed in a first direction perpendicular to the thickness direction of the semiconductor device, and the third lead overlaps with the first and second leads as viewed in a second direction perpendicular to the thickness direction and the first direction.

A semiconductor device provided with first and second semiconductor element each having an obverse and a reverse surface with a drain electrode, source electrode and gate electrode provided on the obverse surface. The semiconductor device is also provided with a control element electrically connected to the gate electrodes of the respective semiconductor elements, and with a plurality of leads, which include a first lead carrying the first semiconductor element, a second lead carrying the second semiconductor element, and a third lead carrying the control element. The first and second leads overlap with each other as viewed in a first direction perpendicular to the thickness direction of the semiconductor device, and the third lead overlaps with the first and second leads as viewed in a second direction perpendicular to the thickness direction and the first direction.

A semiconductor device manufacturing method, includes: a preparing process for preparing a conductive plate, a semiconductor chip arranged over the conductive plate with a first bonding material therebetween, and a connection terminal including a bonding portion arranged over the semiconductor chip with a second bonding material therebetween; a first jig arrangement process for arranging a first guide jig, through which a first guide hole pierces, over the conductive plate, such that the first guide hole corresponds to the bonding portion in a plan view of the semiconductor device; and a first pressing process for inserting a pillar-shaped pressing jig, which includes a pressing portion at a lower end portion thereof, into the first guide hole, and pressing the bonding portion of the connection terminal to a side of the conductive plate with the pressing portion.

In this power semiconductor module, a first lead frame and a second lead frame through which currents flow in opposite directions are arranged so as to overlap each other, whereby the internal inductance can be reduced. In a direction perpendicular to one main surface of a first metal wiring layer, each of the first lead frame and the second lead frame is provided so as not to overlap parts of end surfaces of the first metal wiring layer and a second metal wiring layer. Thus, in a manufacturing process for the power semiconductor module before sealing with sealing resin, it is possible to easily perform positioning between the lead frames and between the metal wiring layer and the lead frame, using the end surfaces, whereby the manufacturing process can be simplified.

A semiconductor package according to an embodiment of the present invention Includes: a lead frame comprising a pad and a lead spaced apart from the pad by a regular interval; a semiconductor chip adhered on the pad; and a clip structure electrically connecting the semiconductor chip and the lead, wherein an one end of the clip structure connected to the semiconductor chip inclines with respect to upper surfaces of chip pads of the semiconductor chip and is adhered to the upper surfaces of the chip pads of the semiconductor chip. A semiconductor package according to another embodiment of the present invention includes: a semiconductor chip comprising one or more chip pads; one or more leads electrically connected to the chip pads; and a sealing member covering the semiconductor chip, wherein an one end of the lead inclines with respect to one surface of the chip pad and is adhered to the chip pad and an other end of the lead is exposed to the outside of the sealing member.

A semiconductor package according to an embodiment of the present invention Includes: a lead frame comprising a pad and a lead spaced apart from the pad by a regular interval; a semiconductor chip adhered on the pad; and a clip structure electrically connecting the semiconductor chip and the lead, wherein an one end of the clip structure connected to the semiconductor chip inclines with respect to upper surfaces of chip pads of the semiconductor chip and is adhered to the upper surfaces of the chip pads of the semiconductor chip. A semiconductor package according to another embodiment of the present invention includes: a semiconductor chip comprising one or more chip pads; one or more leads electrically connected to the chip pads; and a sealing member covering the semiconductor chip, wherein an one end of the lead inclines with respect to one surface of the chip pad and is adhered to the chip pad and an other end of the lead is exposed to the outside of the sealing member.