The present invention relates to an electronic module. In particular, to an electronic module which includes one or more components embedded in an installation base. The electronic module can be a module like a circuit board, which includes several components, which are connected to each other electrically, through conducting structures manufactured in the module. The components can be passive components, microcircuits, semiconductor components, or other similar components. Components that are typically connected to a circuit board form one group of components. Another important group of components are components that are typically packaged for connection to a circuit board. The electronic modules to which the invention relates can, of course, also include other types of components.

A stackable via package includes a substrate having an upper surface and a trace on the upper surface, the trace including a terminal. A solder ball is on the terminal. The solder ball has a solder ball diameter A and a solder ball height D. A via aperture is formed in a package body enclosing the solder ball to expose the solder ball. The via aperture includes a via bottom having a via bottom diameter B and a via bottom height C from the upper surface of the substrate, where A<B and 0=<C<1/2×D. The shape of the via aperture prevents solder deformation of the solder column formed from the solder ball as well as prevents solder bridging between adjacent solder columns.

A land grid array (LGA) land pad having reduced capacitance is disclosed. The conductive portion of a land pad that overlaps a parallel ground plane within the substrate is reduced by one or more non-conductive voids though the thickness of the conductive portion of the land pad. The voids may allow the contact area of the land pad, as defined by the perimeter of the land pad, to remain the same while reducing the conductive portion that overlaps the parallel ground plane. Capacitance between the land pad and the parallel ground plane is reduced by an amount proportional to the reduction in overlapping conductive area.

Circuit board includes conductive plate, core dielectric layer, metallization layer, first build-up stack, second build-up stack. Conductive plate has channels extending from top surface to bottom surface. Core dielectric layer extends on covering top surface and side surfaces of conductive plate. Metallization layer extends on core dielectric layer and within channels of conductive plate. Core dielectric layer insulates metallization layer from conductive plate. First build-up stack is disposed on top surface of conductive plate and includes conductive layers alternately stacked with dielectric layers. Conductive layers electrically connect to metallization layer. Second build-up stack is disposed on bottom surface of conductive plate. Second build-up stack includes bottommost dielectric layer and bottommost conductive layer. Bottommost dielectric layer covers bottom surface of conductive plate. Bottommost conductive layer is disposed on bottommost dielectric layer and electrically connects to metallization layer. First build-up stack includes more conductive and dielectric layers than second build-up stack.

Disclosed are a method, system and device for manufacturing a printed circuit board, and a computer storage medium. The method comprises: acquiring a printed circuit board to be manufactured which includes a via hole; acquiring shape information of the via hole; acquiring connection information of circuit layers in said printed circuit board; assembling preset conducting devices according to the connection information and the shape information, so as to obtain a target conducting device that matches the connection information and the shape information; guiding the target conducting device into the via hole to obtain a conducting printed circuit board; and connecting the conducting printed circuit board to obtain a target printed circuit board, wherein the types of the preset conducting devices comprise a metal conducting device, a non-metal conducting device and a semi-metal conducting device.

A package structure includes a metal layer, a composite layer of a non-conductor inorganic material and an organic material, a sealant, a chip, a circuit layer structure, and an insulating protective layer. The composite layer of the non-conductor inorganic material and the organic material is disposed on the metal layer. The sealant is bonded on the composite layer of the non-conductor inorganic material and the organic material. The chip is embedded in the sealant, and the chip has electrode pads. The circuit layer structure is formed on the sealant and the chip. The circuit layer structure includes at least one dielectric layer and at least one circuit layer. The dielectric layer has conductive blind holes. The insulating protective layer is formed on the circuit layer structure. The insulating protective layer has openings, so as to expose parts of the surface of the circuit layer structure in the openings.

A preparation method of a thin power device comprising the steps of steps S1, S2 and S3. In step S1, a substrate is provided. The substrate comprises a first set of first contact pads and a second set of second contact pads arranged at a front surface and a back surface of the substrate respectively. Each first contact pad of the first set of contact pads is electrically connected with a respective second contact pad of the second set of contact pads via a respective interconnecting structure formed inside the substrate. A through opening is formed in the substrate aligning with a third contact pad attached to the back surface of the substrate. The third contact pad is not electrically connected with the first set of contact pads. In step S2, a semiconductor chip is embedded into the through opening. A back metal layer at a back surface of the semiconductor chip is attached to the third contact pad. In step S3, a respective electrode of a plurality of electrodes at a front surface of the semiconductor chip is electrically connected with said each first contact pad of the first set of contact pads via a respective conductive structure of a plurality of conductive structures.

A method of manufacturing a printed circuit board includes providing a printed circuit board (PCB) substrate including at least one insulating layer and first and second conductive layers separated from one another by the at least one insulating layer, forming a first via hole in the PCB substrate extending from the first conductive layer to the second conductive layer, where the first via hole is defined by a first sidewall of the PCB substrate, forming a second via hole in the PCB substrate, where the second via hole is defined by a second sidewall of the PCB substrate, and selectively plating the first sidewall and the second sidewall to form a first via and a second via, respectively, where the first via and the second via have different via sidewall thicknesses.

Circuit board includes conductive plate, core dielectric layer, metallization layer, first build-up stack, second build-up stack. Conductive plate has channels extending from top surface to bottom surface. Core dielectric layer extends on covering top surface and side surfaces of conductive plate. Metallization layer extends on core dielectric layer and within channels of conductive plate. Core dielectric layer insulates metallization layer from conductive plate. First build-up stack is disposed on top surface of conductive plate and includes conductive layers alternately stacked with dielectric layers. Conductive layers electrically connect to metallization layer. Second build-up stack is disposed on bottom surface of conductive plate. Second build-up stack includes bottommost dielectric layer and bottommost conductive layer. Bottommost dielectric layer covers bottom surface of conductive plate. Bottommost conductive layer is disposed on bottommost dielectric layer and electrically connects to metallization layer. First build-up stack includes more conductive and dielectric layers than second build-up stack.

An interconnect structure includes a first conductor, a second conductor, a dielectric block, a substrate, and a pair of conductive lines. The first conductor and the second conductor form a differential pair design. The dielectric block surrounds the first conductor and the second conductor. The first conductor is separated from the second conductor by the dielectric block. The substrate surrounds the dielectric block and is spaced apart from the first conductor and the second conductor. The pair of conductive lines is connected to the first conductor and the second conductor, respectively, and extends along a top surface of the dielectric block and a top surface of the substrate.