Systems, devices and methods of manufacturing a system on silicon wafer (SoSW) device and package are described herein. A plurality of functional dies is formed in a silicon wafer. Different sets of masks are used to form different types of the functional dies in the silicon wafer. A first redistribution structure is formed over the silicon wafer and provides local interconnects between adjacent dies of the same type and/or of different types. A second redistribution structure may be formed over the first redistribution layer and provides semi-global and/or global interconnects between non-adjacent dies of the same type and/or of different types. An optional backside redistribution structure may be formed over a second side of the silicon wafer opposite the first redistribution layer. The optional backside redistribution structure may provide backside interconnects between functional dies of different types.

A semiconductor assembly includes a semiconductor element having contacts on a first surface electrically connected with contacts of a carrier element by electrically conductive material. A second surface opposite the first surface has a convex curvature with a first radius or a concave curvature with a second radius. The second surface of the convex curvature or the second surface of the concave curvature is connected in a positive-fit manner to a cooling body surface of a concave cooling body curvature of the cooling body, and, during operation at a selected barrier layer temperature, the first radius of the convex curvature deviates by at most 10% from a third radius of the concave cooling body curvature, or the second radius of the concave curvature deviates by at most 10% from a fourth radius of the convex cooling body curvature.

A back plate assembly includes a base plate formed with a groove having a bottom wall and a pair of side walls opposite to each other in a first horizontal direction, and an arch plate assembled into the groove and having a pair of opposite ends in the first horizontal direction. A pair of end surfaces of the ends of the arch plate abut against the side walls and a part of a middle portion of the arch plate between the ends is not in contact with the bottom wall of the groove.

A heat sink includes a first fin and a second fin. The spacing between the first fin and the second fin may be adjusted by a threaded rod. The threaded rod may include a first portion that is engaged with the first fin and a second portion that is engaged with the second fin. The thread pitch of the first portion and the second portion may differ. For example, the pitch of a first internal thread of the first fin may be smaller than the pitch of a second internal thread of the second fin. The spacing of the heat sink fins may be adjusted based upon the current operating conditions of the electronic device to maintain an optimal temperature of a heat generating device during device operation.

The disclosed apparatus may include (1) a shoulder bolt that includes (A) a head and (B) a shank, (2) a retention barrel that envelops at least a portion of the shank of the shoulder bolt, (3) a coil spring that envelops at least a portion of the shank of the shoulder bolt and resides between the head of the shoulder bolt and a heatsink, and (4) a travel-limiting component (such as a set screw or a sleeve) that (A) is coupled to the retention barrel and (B) limits the heatsink from travelling linearly beyond a travel threshold via the coil spring. Various other apparatuses, systems, and methods are also disclosed.

A circuit board assembly is applied to the field of electronic communications technologies to resolve a prior-art heat dissipation problem of a circuit board. The circuit board assembly combines, on a second circuit board, low-speed signals transmitted between a plurality of I/O modules and an IC chip, and then transmits the combined low-speed signals to the IC chip by using a low-speed cable. A low-speed signal sent by the IC chip to the plurality of I/O modules is extended to a plurality of low-speed signals on the second circuit board, and then the plurality of low-speed signals are separately sent to the plurality of I/O modules. This may be applied to a scenario in which a relatively large quantity of electronic components need to be disposed on a circuit board.

A semiconductor assembly includes a semiconductor element having contacts on a first surface electrically connected with contacts of a carrier element by electrically conductive material. A second surface opposite the first surface has a convex curvature with a first radius or a concave curvature with a second radius. The second surface of the convex curvature or the second surface of the concave curvature is connected in a positive-fit manner to a cooling body surface of a concave cooling body curvature of the cooling body, and, during operation at a selected barrier layer temperature, the first radius of the convex curvature deviates by at most 10% from a third radius of the concave cooling body curvature, or the second radius of the concave curvature deviates by at most 10% from a fourth radius of the convex cooling body curvature.

Microelectronic systems and components having integrated heat dissipation posts are disclosed, as are methods for fabricating such microelectronic systems and components. In various embodiments, the microelectronic system includes a substrate having a frontside, a socket cavity, and inner cavity sidewalls defining the socket cavity. A microelectronic component is seated on the frontside of the substrate such that a heat dissipation post, which projects from the microelectronic component, is received in the socket cavity and separated from the inner cavity sidewalls by a peripheral clearance. The microelectronic system further includes a bond layer contacting the inner cavity sidewalls, contacting an outer peripheral portion of the heat dissipation post, and at least partially filling the peripheral clearance.

This heat dissipation structure includes: a circuit board; an integrated circuit mounted thereon; a first thermal pad disposed on the surface of the integrated circuit; a heat sink having a first surface that applies pressure to the first thermal pad by sandwiching the first thermal pad together with the surface of the integrated circuit and a second surface facing the first surface; a second thermal pad disposed on the second surface; a heat dissipation casing having a surface that applies pressure to the second thermal pad by sandwiching the second thermal pad together with the second surface; and stud components for pulling up the heat sink from the heat dissipation casing side together with the circuit board such that the second thermal pad is sandwiched and pressurized between the heat dissipation casing and the heat sink.

A cable connector assembly includes a housing having a first end mounted to an integrated circuit substrate over an integrated circuit component and a second end supporting a heat sink used to dissipate heat from the integrated circuit component. The housing includes a pocket receiving a cable module having a connector housing holding conductors and cables connected to the conductors. The connector housing has a mating end facing the integrated circuit substrate with the conductors arranged at the mating end for interfacing with integrated circuit conductors. A thermal shield is received in the pocket having an opening receiving the cables. The thermal shield has a thermal shielding wall positioned between the cables and the heat sink to provide a thermal barrier between the cables and the heat sink.