A solderable circuit board module system includes at least a first solderable circuit board module and a second solderable circuit board module, wherein the first solderable circuit board module has a first module circuit board having a top side and an underside provided for placement on a motherboard, wherein on the underside of the first module circuit board, solder connection contacts are arranged in a first frame-shaped contact region around a central middle section, which is free of connection contacts. The second solderable circuit board module has additional solder connection contacts, which form an outer frame around the first frame-shaped contact region, as a second group.

A sensor comprises a housing; and a lead frame comprising at least three elongated leads having an exterior portion extending from the housing; and a magnetic sensor circuit disposed in the housing, and connected to the lead frame. The housing comprises two recesses arranged on two opposite sides of the housing for allowing the sensor to be mounted to a support. The lead frame may further comprise a plurality of tabs disposed between the elongated leads, for use as test pins. A component assembly comprising said sensor mounted on a support between deformable protrusions. A method of making said component assembly, comprising the step of positioning said component on the support between said protrusions, and deforming said protrusions such that they are at least partially disposed within the recesses.

A power control module includes a power device having a first side and a second side opposite from the first. The power control module includes a printed wiring board (PWB) spaced apart from the first side of the power device. The PWB is electrically connected to the power device. A heat sink plate is soldered to a second side of the transistor for heat dissipation from the transistor. The PWB and/or the heat sink plate includes an access hole defined therein to allow for access to the transistor during assembly. A method of assembling a power control module includes soldering at least one lead of a power device to a printed wiring board (PWB), pushing the power device toward a heat sink plate, and soldering the power device to the heat sink plate.

Disclosed embodiments include folded, top-to-bottom interconnects that couple a die side of an integrated-circuit package substrate, to a board as a complement to a ball-grid array for a flip-chip-mounted integrated-circuit die on the die side. The folded, top-to-bottom interconnect is in a molded frame that forms a perimeter around an infield to receive at least one flip-chip IC die. Power, ground and I/O interconnections shunt around the package substrate, and such shunting includes voltage regulation that need not be routed through the package substrate.

A power control module includes a power device having a first side and a second side opposite from the first. The power control module includes a printed wiring board (PWB) spaced apart from the first side of the power device. The PWB is electrically connected to the power device. A heat sink plate is soldered to a second side of the transistor for heat dissipation from the transistor. The PWB and/or the heat sink plate includes an access hole defined therein to allow for access to the transistor during assembly. A method of assembling a power control module includes soldering at least one lead of a power device to a printed wiring board (PWB), pushing the power device toward a heat sink plate, and soldering the power device to the heat sink plate.

Provided is a high density multi-component package and a method of manufacturing a high density multi-component package. The high density multi-component package comprises at least two electronic components wherein each electronic component of the electronic components comprise a first external termination and a second external termination. At least one interposer is between the adjacent electronic components and attached to the interposer by an interconnect wherein the interposer is selected from an active interposer and a mechanical interposer. Adjacent electronic components are connected serially.

There is provided an electric connection member having a substrate, an insulating adhesive layer provided on the substrate, and a conductive interconnect, wherein the electric connection member is provided with a recess that opens at a side of the insulating adhesive layer, the conductive interconnect is disposed in the recess, a metal nano-ink is disposed on the conductive interconnect, and all of the metal nano-ink is contained inside the recess.

Provided is a high density multi-component package and a method of manufacturing a high density multi-component package. The high density multi-component package comprises at least two electronic components wherein each electronic component of the electronic components comprise a first external termination and a second external termination. At least one interposer is between the adjacent electronic components and attached to the interposer by an interconnect wherein the interposer is selected from an active interposer and a mechanical interposer. Adjacent electronic components are connected serially.

A power control module includes a power device having a first side and a second side opposite from the first. The power control module includes a printed wiring board (PWB) spaced apart from the first side of the power device. The PWB is electrically connected to the power device. A heat sink plate is soldered to a second side of the transistor for heat dissipation from the transistor. The PWB and/or the heat sink plate includes an access hole defined therein to allow for access to the transistor during assembly. A method of assembling a power control module includes soldering at least one lead of a power device to a printed wiring board (PWB), pushing the power device toward a heat sink plate, and soldering the power device to the heat sink plate.

A substrate structure is provided. The substrate structure includes a first substrate, a plurality of first elastomer pins arranged on the first substrate, an elastic body disposed on the first substrate to surround the plurality of first elastomer pins, the elastic body including a plurality of spaces for receiving a plurality of solder balls on a second substrate connected to the first substrate, and a plurality of solder ball holders arranged on a boundary area of an opening of each of the plurality of spaces, wherein each of the plurality of solder ball holders has strength higher than that of the elastic body, and wherein each of the plurality of solder ball holders includes a plurality of pieces.