A method of die and clip attachment includes providing a clip, a die and a substrate, laminating a sinterable silver film on the clip and the die, depositing a tack agent on the substrate, placing the die on the substrate, placing the clip on the die and the substrate to create a substrate, die and clip package, lead and sintering the substrate, die and clip package.

A clip tape includes connected clip sets; each includes a first clip and a second clip oriented in a same direction, connected by a connector bar. A first multi-chip module and a second multi-chip module are formed by providing a lead frame array containing lead frame units, and providing a clip tape containing connected clip sets. A connected clip set is separated from the clip tape as a unit and placed on the lead frame array; the first clip in the first multi-chip module, and the second clip in the second multi-chip module. The connector bar remains attached during a heating operation, and is severed by a singulation process. A multi-chip module includes a lead frame unit, a semiconductor device, and a clip of a connected clip set attached to the semiconductor device. A connector bar extends from the clip to an external surface of the multi-chip module.

A method of making a plurality of integrated circuit (IC) packages includes picking up a plurality of physically unconnected IC components; and simultaneously placing each of the physically unconnected IC components on corresponding portions of an unsingulated IC package strip that includes a sheet of integrally connected leadframes.

A semiconductor package and a method for making the same are provided. In the method, a clip is used to conduct a lead frame and at least one chip. The clip has at least one second connection segment, at least one third connection segment, and at least one intermediate connection segment. The second connection segment is electrically connected to a second conduction region of the chip and a second pin of the lead frame respectively, and the third connection segment is electrically connected to a third conduction region of the chip and a third pin of the lead frame respectively. The intermediate connection segment connects the at least one second connection segment and the at least one third connection segment, and is removed in a subsequent process. Thereby, the present invention does not need to use any gold wire, which effectively saves the material cost and the processing time.

A circuit includes a conductive clip coupled to at least one component in the circuit. At least one lead portion is located on an end of the clip. The circuit further includes a first lead frame having at least one opening sized to receive the at least one lead portion. The at least one lead portion is received in the at least one opening and the at least one lead portion is an external conductor of the circuit.

A method for forming a panel of stacked semiconductor packages includes providing a bottom leadframe (LF) panel including LFs downset each including at least a plurality of terminals. Low side (LS) transistors are attached to the first die attach area. A first clip panel including first clips downset and interconnected are placed on the bottom LF panel. A dielectric interposer is attached on the first clips over the LS transistors. High side (HS) transistors are attached on the interposers. A second clip panel including a plurality of second clips is mated to interconnect to the HS transistors including mating together the second clip panel, first clip panel and bottom LF panel. The LFs can include a second die attach area, and a controller die attached on the second die attach area, and then pads of the controller die wirebonded to the plurality of terminals.

A method of manufacturing a semiconductor package having a small gate clip is disclosed. A first and second semiconductor chips, each of which includes a source electrode and a gate electrode at a top surface, are attached on two adjacent lead frame units of a lead frame such that the lead frame unit with the first chip formed thereon is rotated 180 degrees in relation to the other lead frame unit with the second semiconductor chip formed thereon. A first and second clip sets are mounted on the first and second semiconductor chips, wherein the first clip set is connected to the gate electrode of the first chip, the source electrode of the second chip, and their corresponding leads and the second clip set is connected to the gate electrode of the second chip, the source electrode of the first chip and their corresponding leads.

A circuit includes a conductive clip coupled to at least one component in the circuit. At least one lead portion is located on an end of the clip. The circuit further includes a first lead frame having at least one opening sized to receive the at least one lead portion. The at least one lead portion is received in the at least one opening and the at least one lead portion is an external conductor of the circuit.

A electronic multi-output device having a substrate including a pad and pins. A composite first chip has a first and a second transistor integrated so that the first terminals of the transistors are merged into a common terminal on one chip surface. Patterned second and third terminals are on the opposite chip surface. The common first terminal is attached to the substrate pad. The second terminals are connected by discrete first and second metal clips to respective substrate pins. A composite second chip has a third and a fourth transistor integrated so that the second terminals of the transistors are merged into a common terminal on one chip surface. Patterned first and third terminals are on the opposite chip surface. The second chip is flipped to be vertically attached with its first terminals to the first and second clips, respectively. The third terminals are connected by discrete clips to respective substrate pins. The common second terminal is connected by a common clip to a substrate pin.

The power module includes: a ceramics substrate; a source electrode pattern, a drain electrode pattern, a source signal electrode pattern, and a gate signal electrode pattern respectively disposed on the ceramics substrate; a semiconductor device disposed on the drain electrode pattern, the semiconductor device comprising a source pad electrode and a gate pad electrode at a front surface side; a divided leadframe for source bonded to the source electrode pattern and the source pad electrode; and a divided leadframe for gate pad electrode bonded to a gate pad electrode. There is provided a power module having a simplified structure, fabricated through a simplified process, and capable of conducting a large current; and a fabrication method for such a power module.