A width of each of a first signal terminal and a reference potential terminal formed in a first connection region of a core insulating layer constituting a flexible substrate is larger than a width of each of a first backside signal terminal and a backside reference potential terminal formed in a second connection region of the core insulating layer. In addition, a first separation distance between the first signal terminal and the reference potential terminal arranged adjacent to the first signal terminal is smaller than a second separation distance between the first backside signal terminal and the backside reference potential terminal arranged adjacent to the first backside signal terminal. An insulating film formed on a first surface of the core insulating layer at a position overlapping each of the first connection region and the second connection region covers the first connection region such that the second connection region is exposed.

A transition structure between a transmission line of a multilayer PCB and a waveguide is proposed. The transition structure includes the waveguide comprising an interior space on one side thereof and having an inlet for accommodating a part of a stripline, the transmission line comprising a first ground layer of the multilayer PCB composed of at least two or more dielectric layers, the stripline extending from the transmission line and protruding into the waveguide through the inlet of the waveguide, and a single via hole or a plurality of via holes formed between the first ground layer and a bottommost ground layer, wherein each via hole is positioned at the inlet of the waveguide.

A multiple layer printed circuit board including a plurality of layers, vertical interconnect accesses (VIAs), and a vertical interconnect access (VIA) bridge. The layers may include signal layers, prepreg substrate layers disposed between the signal layers, ground plane layers, wherein each of the ground plane layers abuts one of the prepreg substrate layers, inner signal layers, wherein each of the inner signal layers abuts one of the prepreg substrate layers, and a core substrate layer disposed between the signal layers, wherein two of the inner signal layers abut opposed sides of the core substrate layer. The VIAs extend through at least some of the layers, wherein each of the VIAs is formed by aligned apertures through adjoining ones of the prepreg substrate layers, ground plane layers, and inner signal layers. The VIA bridge is coupled to the VIAs to convey heat to a heat sink.

An integrated circuit device includes an integrated circuit device die and a substrate. The integrated circuit device die includes a plurality of first contact pads. The first contact pads include a pair of first signal contact pads configured to provide a differential signal port of the integrated circuit device die. The differential signal port is configured to operate at a predetermined frequency. The substrate includes a plurality of second contact pads on a first surface of the substrate. The second contact pads are configured to be soldered to a printed circuit board, and include a pair of second signal contact pads. The integrated circuit device die is affixed to a second surface of the substrate via the first contact pads. The substrate includes a pair of circuit paths that each couple one of the first signal contact pads to an associated one of the second signal contact pads. The pair of circuit paths each have a length to provide a half-wave matching network at the predetermined frequency to match a single-ended signal at the pair of second signal pads to the differential signal port.

The present disclosure relates to a printed circuit board. The printed circuit board includes a core layer; a through portion penetrating through the core layer; a first via disposed to be spaced apart from an inner wall of the through portion within the through portion; and a second via disposed in the first via and having a diameter different from that of the first via.

A wiring board includes a pair of hard substrates provided for each of a plurality of semiconductor elements connected in parallel; a soft substrate provided so as to be at least partially sandwiched between all of the pairs of hard substrates; a first electrode configured to connect a control terminal of the semiconductor element and the hard substrate or the soft substrate; a second electrode configured to connect a reference potential terminal of the semiconductor element and the hard substrate or the soft substrate; a first wiring configured to connect in parallel the first electrodes of each of the plurality of semiconductor elements, at least part of the first wiring being provided on the soft substrate; and a second wiring configured to connect in parallel the second electrodes of each of the plurality of semiconductor elements, at least part of the second wiring being provided on the soft substrate.

Devices are disclosed that include a wideband millimeter wave (mmW) via transition design for multilayer printed circuit boards (MLBs). In various instances embodiments, a via is dimensioned to provide impedance matching to stripline tracing connected at the end of the via. Impedance matching in the via may eliminate the need for an impedance matching section on the stripline tracing. In some instances, the dimensions of the via pad diameter and the via keepout diameter are selected to tune a via transition structure to selected frequencies and/or frequency bandwidths.

Electromagnetic circuit structures and methods are provided for a circuit board that includes a hole disposed through a substrate to provide access to an electrical component, such as a signal trace line (or stripline), that is at least partially encapsulated (e.g., sandwiched) between substrates. The electrical component includes a portion substantially aligned with the hole, and an electrical conductor is disposed within the hole. The electrical conductor is soldered to the portion of the electrical component.

The disclosure relates to a machining station for machining platelike workpieces (1) by means of at least one tool (10, 13, 14). The machining station has a measuring device (16) for acquiring data relating to the position of bores, a drill (10, 13, 14) for generating bores in the workpiece (1), and a data processor (17) for processing data of the at least one measuring device (16) and/or for controlling the at least one drill (10, 13, 14). The data processor (17) is here suitable and set up for performing an adjustment between a desired drilling position and/or a desired bore depth and an actual position and/or actual depth as determined by the at least one measuring device (16) for a bore present in the workpiece (1), and adapting the drilling position and/or bore depth for generating bores by means of the at least one drill (10, 13, 14).

A component carrier includes a stack with at least one electrically conductive layer structure, at least one electrically insulating layer structure, and a hole in the stack having a first hole portion covered with metal and having a second hole portion not covered with metal, wherein the second hole portion is defined by an anti-plating dielectric structure and an electroless plateable separation barrier.