A semiconductor package and a method of forming the semiconductor package are provided. The method includes providing a first substrate, forming a wiring structure containing at least two first wiring layers, disposing a first insulating layer between adjacent two first wiring layers, and patterning the first insulating layer to form a plurality of first through-holes. The adjacent two first wiring layers are electrically connected to each other through the plurality of first through-holes. The method also includes providing at least one semiconductor element each including a plurality of pins. In addition, the method includes disposing the plurality of pins of the each semiconductor element on a side of the wiring structure away from the first substrate. Further, the method includes encapsulating the at least one semiconductor element, and placing a ball on a side of the wiring structure away from the at least one semiconductor element.

An optoelectronic component includes a first housing body and a second housing body separate from the first housing body. A first section of a leadframe is embedded into the first housing body. A second section of the leadframe connected integrally the first section, is embedded into the second housing body.

A semiconductor package includes a semiconductor element, a wiring structure, an encapsulation structure, and a solder ball. The semiconductor element includes a plurality of pins. A side of the wiring structure is electrically connected to the plurality of pins of the semiconductor element. The wiring structure includes at least two first wiring layers. A first insulating layer is disposed between adjacent two first wiring layers of the at least two first wiring layers. The first insulating layer includes a plurality of first through-holes. The adjacent two first wiring layers are electrically connected to each other through the plurality of first through-holes. The encapsulation structure at least partially surrounds the semiconductor element. The solder ball is located on a side of the wiring structure away from the semiconductor element. The solder ball is electrically connected to the at least two first wiring layers.

A wire structure (50A) includes: a column-like bump (45), provided to be adjacent to a second electronic component (32b) installed on a substrate (31); and a looping wire (50), bonded onto the substrate (31) to stride over the second electronic component (32b). The looping wire (50) includes: a second raised part (54), wherein a tip is bonded to the substrate (31) on a side of the column-like bump (45) opposite to the second electronic component (32b) to be raised from the substrate (31); a loop part (55), extending to stride over the second electronic component (32b); and a bent part (56), bent to be engaged with an upper end of the column-like bump (45) to connect the loop part (55) and the second raised part (54).

The present disclosure provides a photovoltaic stringer and a method for manufacturing a photovoltaic ribbon. The photovoltaic stringer includes a first clamping component to pull a ribbon from a ribbon reel, a second clamping component to coordinate with the first clamping component to stretch the ribbon, a cutting component to cut the ribbon, and, at least one first electrode and at least one second electrode to supply power to the ribbon. The method for manufacturing a photovoltaic ribbon comprises acquiring a ribbon reel and pulling a ribbon, stretching the ribbon and cutting the ribbon to obtain a cut ribbon, and performing an annealing process on the cut ribbon.

A semiconductor package and a method of forming the semiconductor package are provided. The method includes providing a first substrate, forming a wiring structure containing at least two first wiring layers, disposing a first insulating layer between adjacent two first wiring layers, and patterning the first insulating layer to form a plurality of first through-holes. The adjacent two first wiring layers are electrically connected to each other through the plurality of first through-holes. The method also includes providing at least one semiconductor element each including a plurality of pins. In addition, the method includes disposing the plurality of pins of the each semiconductor element on a side of the wiring structure away from the first substrate. Further, the method includes encapsulating the at least one semiconductor element, and placing a ball on a side of the wiring structure away from the at least one semiconductor element.

Disclosed herein are microelectronics packages that include thermal pillars for at least localized extraction of generated heat and methods for manufacturing the same. The microelectronics packages may include a substrate and a plurality of dies stacked on the substrate with at least one of the plurality of dies connected to the substrate. A heat spreader may be located proximate at least a portion of the plurality of dies. Respective thermal pillars from a plurality of thermal pillars may extend from at least one of the plurality dies to the heat spreader. Each of the plurality of thermal pillars may define a respective pathway from at least one of the plurality of dies to the heat spreader.

The present disclosure provides a photovoltaic stringer and a method for manufacturing a photovoltaic ribbon. The photovoltaic stringer includes a first clamping component to pull a ribbon from a ribbon reel, a second clamping component to coordinate with the first clamping component to stretch the ribbon, a cutting component to cut the ribbon, and, at least one first electrode and at least one second electrode to supply power to the ribbon. The method for manufacturing a photovoltaic ribbon comprises acquiring a ribbon reel and pulling a ribbon, stretching the ribbon and cutting the ribbon to obtain a cut ribbon, and performing an annealing process on the cut ribbon.

A micro-coaxial wire has an overall diameter in a range of 0.1 m-550 m, a conductive core of the wire has a cross-sectional diameter in a range of 0.05 m-304 m, an insulator is disposed on the conductive core with thickness in a range of 0.005 m-180 m, and a conductive shield layer is disposed on the insulator with thickness in a range of 0.009 m-99 m.

A method includes aligning a wire with a package body having a contact pad and moving the wire through the package body to form electrical contact with the contact pad.