A power module includes a substrate that is electrically insulative and includes a substrate main surface and a substrate back surface at opposite sides in a thickness direction. The power module also includes a mounting layer that is conductive and arranged on the substrate main surface. The power module further includes a graphite plate having anisotropic thermal conductivity and including a plate main surface and a plate back surface at opposite sides in the thickness direction. The plate back surface is connected to the mounting layer. The power module further includes a power semiconductor element arranged on the plate main surface.

A semiconductor package disposed on a base is provided. The semiconductor package includes a semiconductor chip and a redistribution layer (RDL) structure. The semiconductor chip includes a first chip pad and a second chip pad. The redistribution layer (RDL) structure partially covers the semiconductor chip and is separated from the base by the semiconductor chip. The RDL structure includes a redistribution layer (RDL) trace having a first terminal and a second terminal. The first terminal of the RDL trace is electrically coupled to the first chip pad. The second terminal of the RDL trace is electrically coupled to the second chip pad.

Embodiments include a microelectronic package structure having a substrate with one or more substrate pads on a first side of the package substrate. A ball interconnect structure is on the substrate pad, the ball interconnect structure comprising at least 99.0 percent gold. A discrete component having two or more component terminals is on the ball interconnect structure.

An optical receiver module includes a light receiving element that has a first electrode and a second electrode for receiving a bias and converts an optical signal inputted into an electrical signal to output the electrical signal via the first electrode. A signal line extends from the first electrode through the light receiving element-side signal pad and the second wire to the amplifier-side signal pad. A bias line extends from the second electrode through the light receiving element-side bias pad, the first wire, and the third wire to the first and second amplifier-side bias pads. The signal line three-dimensionally intersects with the bias line at an interval in a direction of the loop height of the first wire and that of the second wire.

A circuit board and package assembly electrically connecting a die to a circuit board. The circuit board has signal paths terminating in a signal pad located on an insulating layer. The circuit board also includes a ground pad on the insulating layer that has a concave shaped side forming a recess, the with a signal pad at least partially within the recess. A package has package ground pads aligned with the circuit board ground pads and package signal pads aligned with circuit board signal pads. The package ground pads extend through the package to connect to package ground paths, which extend toward the die. The package signal pads extend through the package to connect to package signal paths and the package signal paths extend toward the die, maintaining a consistent distance from the package ground paths. Multiple-tier bond wires connect the package bond locations to the die bond pads.

A stacked die power converter package includes a lead frame including a die pad and a plurality of package pins, a first die including a first power transistor switch (first power transistor) attached to the die pad, and a first metal clip attached to one side of the first die. The first metal clip is coupled to at least one package pin. A second die including a second power transistor switch (second power transistor) is attached to another side on the first metal clip. A controller is provided by a controller die attached to a non-conductive layer on the second metal clip on one side of the second die.

A packaged electronic device includes a package structure with opposite first and second sides spaced apart from one another along a first direction, and opposite third and fourth sides spaced apart from one another along a second direction, as well as first and second leads. The first lead includes a first portion that extends outward from the third side of the package structure and extends downward toward a plane of the first side and away from a plane of the second side. The second lead includes a first portion that extends outward from the third side of the package structure, and the second lead extends upward toward the plane of the second side and away from the plane of the first side to allow connection to another circuit or component, such as a second packaged electronic device, a passive circuit component, a printed circuit board, etc.

In order to form, in a wide band gap semiconductor device, a high field resistant sealing material having a large end portion film thickness, said high field resistant sealing material corresponding to a reduced termination region having a high field intensity, and to improve accuracy and shorten time of manufacturing steps, this semiconductor device is configured as follows. At least a part of a cross-section of a high field resistant sealing material formed close to a termination region at the periphery of a semiconductor chip has a perpendicular shape at a chip outer peripheral end portion, said shape having, on the chip inner end side, a film thickness that is reduced toward the inner side. In a semiconductor device manufacturing method for providing such semiconductor device, the high field resistant sealing material is formed in a semiconductor wafer state, then, heat treatment is performed, and after dicing is performed, a chip is mounted.

A die package having lead structures connecting to a die that provide for electromagnetic interference reductions. Mixed impedance leads connected to the die have a first lead with a first metal core, a dielectric layer surrounding the first metal core, and first outer metal layer connected to ground; and a second lead with a second metal core, and a second dielectric layer surrounding the second metal core, and a second outer metal layer connected to ground. Each lead reducing susceptibility to EMI and crosstalk.

An electronic package structure and a chip thereof are provided. The electronic package structure includes a substrate, a chip, a plurality of signal wires, and a core ground wire. The chip disposed on and electrically connected to the substrate has a core wiring region and an input and output pad region located at a top surface thereof. The input and output pad region is located between the core wiring region and an edge of the chip. The chip includes a plurality of signal pads in the input and output region and a core ground pad adjacent to one of the signal pads. The core ground pad located in the core wiring region. The signal wires are respectively connected to the signal pads. The core ground wire connected to the core ground pad is adjacent to and shields one of the signal wires.