Embodiments may relate to a microelectronic package or a die thereof which includes a die, logic, or subsystem coupled with a face of the substrate. An inductor may be positioned in the substrate. Electromagnetic interference (EMI) shield elements may be positioned within the substrate and surrounding the inductor. Other embodiments may be described or claimed.

Multiple designs for a multi-layer circuit may be simulated to determine impedance profiles of each design, allowing a circuit designer to select a design based on the impedance profiles. One feature that can be modified is the structure surrounding the barrels of a differential VIA on layers that are not connected to the differential VIA. Specifically, one antipad can be used that surrounds both barrels or two antipads can be used, with one antipad for each barrel. Additionally, the size of the antipad or antipads can be modified. These modifications affect the impedance of the differential VIA. Additionally, a conductive region may be placed that connects to the VIA barrel even though the circuit on the layer does not connect to the VIA. This unused pad, surrounded by a non-conductive region, also affects the impedance of the differential VIA.

Embodiments may relate to a microelectronic package or a die thereof which includes a die, logic, or subsystem coupled with a face of the substrate. An inductor may be positioned in the substrate. Electromagnetic interference (EMI) shield elements may be positioned within the substrate and surrounding the inductor. Other embodiments may be described or claimed.

Multiple designs for a multi-layer circuit may be simulated to determine impedance profiles of each design, allowing a circuit designer to select a design based on the impedance profiles. One feature that can be modified is the structure surrounding the barrels of a differential VIA on layers that are not connected to the differential VIA. Specifically, one antipad can be used that surrounds both barrels or two antipads can be used, with one antipad for each barrel. Additionally, the size of the antipad or antipads can be modified. These modifications affect the impedance of the differential VIA. Additionally, a conductive region may be placed that connects to the VIA barrel even though the circuit on the layer does not connect to the VIA. This unused pad, surrounded by a non-conductive region, also affects the impedance of the differential VIA.

Example embodiments relate to power dividers. One example power divider includes a dielectric unit that includes one or more dielectric layers and has a first surface and a second surface. The power divider also includes a first transmission line unit being of a coplanar type or a stripline type. The first transmission line unit includes a plurality of first transmission lines, each first transmission line including a respective first line segment and a respective second line segment. The first transmission line unit also includes a first dielectric layer. The power divider also includes a second transmission line unit. The second transmission line unit includes a second transmission line. The second transmission line unit also includes a second dielectric layer. Further, the power divider includes a first via. In addition, the power divider includes a plurality of second vias distributed around the first via.

An electronic component mounting substrate according to an embodiment of the present disclosure includes a substrate and a plurality of via conductors. The substrate includes a mounting region where an electronic component is to be mounted, and one or more insulating layers. The plurality of via conductors extend through the one or more insulating layers in a thickness direction of the substrate. The plurality of via conductors are arranged, in a plan view of the one or more insulating layers, in m columns in an X direction and n rows in a Y direction, where m and n are natural numbers, and positioned either in odd-numbered rows of odd-numbered columns and even-numbered rows of even-numbered columns only, or in even-numbered rows of odd-numbered columns and odd-numbered rows of even-numbered columns only.

A circuit board according to an embodiment includes: a substrate including one surface and the other surface; a first circuit pattern disposed on the one surface; and a second circuit pattern disposed on the other surface, wherein at least one via is formed in the substrate, and the first circuit pattern and the second circuit pattern are wire-bonded through the via to conduct electricity.

An interposer-type component carrier includes a stack comprising at least one electrically conductive layer structure and at least one electrically insulating layer structure; a cavity formed in an upper portion of the stack; an active component embedded in the cavity and having at least one terminal facing upwards; and a redistribution structure having only one electrically insulating layer structure above the component. A method of manufacturing an interposer-type component carrier is also disclosed.

In a printed circuit board (1), thermal vias (19) are formed between the lower surface (A) and an upper surface (B) of the substrate plate (10) of the printed circuit board through the steps of: applying a respective solder resist mask (21, 31) to the lower surface (A) and the upper surface (B); applying solder to the lower surface (A) and reflow soldering the solder, wherein the solder penetrates into the boreholes (20) and forms convex menisci (26) protruding beyond the edge (22) of the respective boreholes on the lower surface (A); and creating regions (35) on the upper surface (B), which are freed from solder resist material, and which are intended for contacting at least one electronic component (17) on the upper surface and each of which comprise at least one of the thermal vias. Subsequently, the upper surface (B) can be provided with electrical components (17) on these regions (35). The first solder resist mask (21) has a respective region (23) that is free of solder resist on the lower surface around the edge of every borehole (20).

A system package module is provided. The system package module includes a module substrate, a plurality of first pins and a plurality of second pins. The module substrate includes a module substrate surface. The module substrate surface includes a first pin arrangement area and a second pin arrangement area. The second pin arrangement area surrounds the first pin arrangement area. The first pins are disposed in the first pin arrangement area. A first pin gap is formed between the two adjacent first pins. The second pins are disposed in the second pin arrangement area. A second pin gap is formed between the two adjacent second pins. The first pin gap is greater than the second pin gap.