A method for manufacturing a semiconductor module includes the step of soldering two or more semiconductor elements having substrate materials and heights different from each other to a metal foil disposed at one side of an insulating substrate; connecting a plurality of wiring members, not interconnecting the semiconductor elements, to front face electrodes of the semiconductor elements through solder so that heights from a surface of the insulating substrate to top faces of the wiring members become same level with each other; inspecting a leakage current while applying electricity on each one of semiconductor elements individually through the wiring members; and connecting the top faces of the wiring members with a bus bar.

A semiconductor device according to the present invention includes a plurality of semiconductor chips, a plate electrode disposed on the plurality of semiconductor chips for connecting the plurality of semiconductor chips, and an electrode disposed on the plate electrode. The electrode has a plurality of intermittent bonding portions to be bonded to the plate electrode and a protruded portion which is protruded erectly from the bonding portions. The protruded portion has an ultrasonic bonding portion which is parallel with the bonding portion and is ultrasonic bonded to an external electrode.

A combined packaged power semiconductor device includes flipped top source low-side MOSFET electrically connected to top surface of a die paddle, first metal interconnection plate connecting between bottom drain of a high-side MOSFET or top source of a flipped high-side MOSFET to bottom drain of the low-side MOSFET, and second metal interconnection plate stacked on top of the high-side MOSFET chip. The high-side, low-side MOSFET and the IC controller can be packaged three-dimensionally reducing the overall size of semiconductor devices and can maximize the chip's size within a package of the same size and improves the performance of the semiconductor devices. The top source of flipped low-side MOSFET is connected to the top surface of the die paddle and thus is grounded through the exposed bottom surface of die paddle, which simplifies the shape of exposed bottom surface of the die paddle and maximizes the area to facilitate heat dissipation.

A semiconductor device in which even when cracks occur in a sealing material, the entry of moisture through the cracks can be prevented. A semiconductor device comprising a semiconductor element 11 mounted on a laminated substrate 12 and an electrically conductive connecting member, and a sealing material which seals the semiconductor element and the electrically conductive connecting member, wherein the sealing material includes a sealing layer 20 sealing members to be sealed including the laminated substrate 12, the semiconductor element 11, and the electrically conductive connecting member and including a thermosetting resin, and a protective layer 21 coating the sealing layer and including a silicone rubber, and wherein a value A.sub.1 of a tensile strength × elongation at break of the sealing layer 20 is less than a value A.sub.2 of a tensile strength × elongation at break of the protective layer 21, and the A.sub.2 is 1600 MPa or less.

An electrode terminal includes a body and a first bonding part. The body includes a first metal material. Then, the first bonding part is bonded to one end of the body, and includes a second metal material which is a clad material other than the first metal material. The first bonding part is ultrasonically bondable to a first bonded member. An elastic part which is elastically deformable is provided between the one end of the body and the other end of the body.

An embodiment of a power-supply module includes a package having sides, a first power-supply component disposed in the package, and an electromagnetic-interference (EMI) shield disposed adjacent to two sides of the package. For example, such a module may include component-mounting platforms (e.g., a lead frame or printed circuit board) on the top and bottom sides of the module, and these platforms may provide a level of EMI shielding specified for a particular application. Consequently, such a module may provide better EMI shielding than modules with shielding along only one side (e.g., the bottom) of the module. Moreover, if the module components are mounted to, or otherwise thermally coupled to, the shielding platforms, then the module may provide multi-side cooling of the components.

Improvement in yield of a semiconductor device is obtained. In addition, increase in service life of a socket terminal is obtained. A projecting portion PJ1 and a projecting portion PJ2 are provided in an end portion PU of a socket terminal STE1. Thus, it is possible to enable contact between a lead and the socket terminal STE in which a large current is caused to flow, at two points by a contact using the projecting portion PJ1 and by a contact using the projecting portion PJ2, for example. As a result, the current flowing from the socket terminal STE1 to the lead flows by being dispersed into a path flowing in the projecting portion PJ1 and a path flowing in the projecting portion PJ2. Accordingly, it is possible to suppress increase of temperature of a contact portion between the socket terminal STE1 and the lead even in a case where the large current is caused to flow between the socket terminal STE1 and the lead.

A semiconductor module includes first to fourth semiconductor elements, each having an upper-surface electrode and a lower-surface electrode, first to fourth conductive layers, each extending in a first direction and being independently disposed side by side in a second direction orthogonal to the first direction, and an output terminal connected to the second and third conductive layers. The lower-surface electrodes of each of the first to fourth semiconductor elements are respectively conductively connected to the first to fourth conductive layers. The third conductive layer and the fourth conductive layer are disposed between the first conductive layer and the second conductive layer and are connected to the output terminal to have an equal potential.

Semiconductor device A1 of the present disclosure includes: semiconductor element 10 (semiconductor elements 10A and 10B) having element obverse face and element reverse face facing toward opposite sides in z direction; support substrate 20 supporting semiconductor element 10; conductive block 60 (first block 61 and second block 62) bonded to element obverse face via first conductive bonding material (block bonding materials 610 and 620); and metal member (lead member 40 and input terminal 32) electrically connected to semiconductor element 10 via conductive block 60. Conductive block 60 has a thermal expansion coefficient smaller than that of metal member. Conductive block 60 and metal member are bonded to each other by a weld portion (weld portions M4 and M2) at which a portion of conductive block 60 and a portion of metal member are welded to each other. Thus, the thermal cycle resistance can be improved.

A semiconductor device encompasses a cooler made of ceramics, having a first main face and a second main face, being parallel and opposite to the first main face, defined by two opposite side faces perpendicular to the first and second main faces, a plurality of conductive-pattern layers delineated on the first main face, a semiconductor chip mounted on the first main face via one of the plurality of conductive-pattern layers, and a seal member configured to seal the semiconductor chip.