Provided is a circuit board structure including a substrate, a loop-wrapping ground layer, an insulating structure, a first build-up layer, a top wiring layer, a bottom wiring layer, a first conductive via, and a plurality of second conductive vias. The aforementioned structure defines a signal transmitting structure. An equivalent circuit of the signal transmitting structure at least includes a first equivalent circuit, a second equivalent circuit, a third equivalent circuit and a fourth equivalent circuit, which correspond to different uniform transmitting sections respectively. The first equivalent circuit, the second equivalent circuit, the third equivalent circuit and the fourth equivalent circuit are connected in series with each other according to an ABCD transmission matrix series connection principle.

Systems and assemblies are provided for transposition channel routing where the characteristics of an escape route can be modified on a printed circuit board (PCB) in a manner that reduces crosstalk and realizes significant signal quality improvement. The techniques involve “transposition” of a signal line pair on the PCB, reduces effect coupling coefficients for individual aggressor signals, thereby reducing the crosstalk. Transposition channel routing techniques can also be applied to other areas on a PCB (e.g., other than escape routes) where space is constrained and other mitigation techniques are not possible. The PCB can include an array of contact pads, a plurality of signal line pairs that include an escape route. One or more transposition junctions disposed within the escape route can route a signal line pair from a first routing channel in the escape route into a second routing channel in the escape route.

A mixed pitch method of placing pads in a ball grid array (BGA) package having a BGA substrate and a plurality of connectors arranged in an array and connected via the pads to the BGA substrate. Selected pairs of the pads are placed on the BGA substrate at a distance defined by a first pitch P1. Ground pads are placed on the BGA substrate at a distance from the selected pairs of pads defined by a second pitch P2, wherein P2=M*P1 and M is greater than one. The selected pairs of the pads on the BGA substrate are also placed at a distance from other selected pairs of the pads defined by the second pitch P2.

A module substrate for a semiconductor module including a wiring substrate having an upper surface and a lower surface opposite to each other and including a wiring formed therein, the wiring substrate having at least one through groove in at least one sidewall and extending in a thickness direction, and a through-groove test terminal including at least one contact pad, a surface of the contact pad being exposed from an inner wall of the through-groove, the contact pad being spaced apart from a vertical plane extending from the sidewall of the wiring substrate may be provided.

Provided is a display device and an electronic apparatus that prevent the occurrence of failure in the connection between a mounting substrate and an electronic component. The display device includes an interconnection layer provided on a support substrate, a plurality of insulating layers provided above the interconnection layer, an opening provided in parts of the insulating layers, and a metal layer electrically connected to the interconnection layer and filling the opening up to a height below a layer surface of the insulating layer.

An electronic substrate connects to a semiconductor component via a plurality of front surface terminals disposed in an array on a front surface and connects to a main substrate via a plurality of back surface terminals disposed in an array on a back surface. The electronic substrate includes: a first wiring that electrically connects the front surface terminals and the back surface terminals in the electronic substrate and is supplied with power supply from the main substrate via the back surface terminals; and a second wiring that electrically connects the front surface terminals and the back surface terminals in the electronic substrate, is supplied with power supply having the same potential as the first wiring from the main substrate via the back surface terminals, and is not electrically connected to the first wiring in the electronic substrate.

The present disclosure provides a multilayer wiring structure, including a plurality of dielectric layers, a plurality of conductive wiring layers interleaved with the plurality of dielectric layers, wherein the plurality of conductive wiring layers includes copper-phosphorous alloys (such as Cu.sub.3P).

A ceramic electronic device includes a multilayer chip having dielectric layers and internal electrode layers and having a first main face and a second main face that have a rectangular shape in a planar view, external electrodes each of which extends from the first main face to the second main face at each of two diagonal corners of the rectangular shape, the external electrodes being spaced from each other, each of the external electrodes being connected to a part of the internal electrode layers, and a conductor that is provided on the first main face, the second main face or both of the first main face and the second main face, is spaced from the external electrodes, and is provided in a region which includes an intersection point of perpendicular bisectors of two adjacent sides of the rectangular shape.

A semiconductor device package includes a substrate, a connection structure, a first package body and a first electronic component. The substrate has a first surface and a second surface opposite to the first surface. The connection structure is disposed on the first surface of the substrate. The first package body is disposed on the first surface of the substrate. The first package body covers the connection structure and exposes a portion of the connection structure. The first electronic component is disposed on the first package body and in contact with the portion of the connection structure exposed from the first package body.

A circuit board includes a substrate including first and second sections with different thicknesses, a protective layer, and mounting electrodes. The substrate includes a step surface connecting a first principal surface of the first section and a first principal surface of the second section. The mounting electrodes are on the first principal surface corresponding to an element to be mounted. The protective layer is disposed over the first principal surface, the step surface, and the first principal surface. The separation distance between the mounting electrode and the step surface is greater than or equal to the terminal-to-terminal distance between the mounting electrode and the mounting electrode.