The present subject matter relates to a battery module for use in a vehicle. The battery module may include a housing, a plurality of battery cells disposed within the housing, and solid state pre-charge control circuitry that pre-charges a direct current (DC) bus that may be coupled between the battery module and an electronic component of the vehicle. Furthermore, the solid state pre-charge control circuitry may include solid state electronic components as well as passive electronic components.

An electronic device according to various embodiments comprises: a circuit element; a printed circuit board comprising a first connection pad connected to the ground of the electronic device, a second connection pad, and a third connection pad arranged between the first connection pad and the second connection pad and connected to a signal terminal of the circuit element; and a flexible printed circuit board (FPCB) comprising a coupling part connected to the printed circuit board, and a connection part extending from the coupling part, wherein the FPCB comprises first ground wiring connected to the first connection pad and extending from the coupling part to the connection part in an assigned direction, second ground wiring connected to the second connection pad and extending from the coupling part to the connection part in the assigned direction, signal wiring connected to the third connection pad and extending from the coupling part to the connection part in the assigned direction, while being arranged between the first ground wiring and the second ground wiring, and third ground wiring arranged in an opposite direction to the assigned direction so as to be connected, in the coupling part, to the first ground wiring and the second ground wiring and surround the signal wiring. Other various embodiments are possible.

A flexible printed circuit board includes a power wiring layer transmitting power and a signal wiring layer insulated and stacked over or under the power wiring layer.

Various embodiments of laminated planar bus structures that minimize electromagnetic interference (EMI) and parasitic inductance are described. In one embodiment, a laminated planar bus structure may include a plurality of stacked conductive layers and a plurality of stacked insulation layers. The plurality of stacked conductive layers may include positive and negative conductive layers, and conductive ground layers stacked as outer layers as to enclose vertically the positive and the negative conductive layers. In another embodiment, the laminated planar bus structure may include a middle ground layer stacked in between the positive and the negative conductive layers to provide additional reduction in electric field strength. A laminated planar bus structure that is integrated with other power electronics components is also presented.

A printed circuit board (PCB) includes a substrate defining a major plane. A first side of the major plane is configured for mounting of functional circuit elements. A cable connector is mounted on a second side of the major plane of the substrate, opposite the first side, for coupling to a shielded radiofrequency (RF) communications cable. At least one component grounding layer is parallel to the major plane and configured for coupling to the functional elements. At least one cable grounding layer is parallel to the major plane and is separated from the at least one component grounding layer. Each cable grounding layer in the at least one cable grounding layer is coextensive with the substrate and is configured for coupling, through the connector, to shielding of the shielded RF communications cable, without coupling to any other component. Nodes of an RF communications system may be mounted on such PCBs.

A battery module includes a housing, a plurality of battery cells disposed in the housing, and a printed circuit board (PCB) assembly disposed in the housing. The PCB assembly includes a PCB and a shunt disposed across a first surface of the PCB. A second surface of the shunt directly contacts the first surface of the PCB, and the shunt is electrically coupled between the battery cells and a terminal of the battery module.

Systems, apparatus, methods for manufacturing and techniques for interconnecting integrated circuit devices are disclosed. A flexible printed circuit (FPC) provides EMI shielding with reduced insertion loss. The FPC includes a first signal layer fabricated from a planar conductive material and having traces configured to carry signals between a circuit boards. The FPC may include a first non-conductive layer disposed in a plane above the first signal layer, a second non-conductive layer disposed in a plane below the first signal layer, a first copper ground plane disposed in a plane above the first non-conductive layer, a second copper ground plane disposed in a plane below the second non-conductive layer, and a second signal layer provided in a plane above the first copper ground plane or below the second copper ground plane. Signals carried in the first signal layer may have a higher frequency than signals carried in the second signal layer.

A printed circuit board (PCB) may include a signal layer having a functional region and a PCB signal layer testing region. The PCB signal layer testing region may include a first differential pair having a first length formed on the signal layer, a second differential pair having a second length, different than the first length, formed on the signal layer and a third differential pair having a third length, different than the first length and different than the second length, formed on the signal layer.

Apparatuses and methods for routing and transmitting signals in an electronic device are described. Various signal paths may be routed to avoid or limit reference transitions or transitions between layers of a structure of a device (e.g., printed circuit board (PCB)). In a memory module, for example, different data inputs/outputs (e.g., DQs) may be routed through different layers of a PCB according to their relative location to one another. For instance, DQs associated with even bits of a byte may be routed on one layer of a PCB near one ground plane, and DQs associated with odd bits of the byte may be routed on a different layer of the PCB near another ground plane.

A multiple layer printed circuit board (PCB) in which the cores (or core layers) are removed and replaced with prepreg layers, which provide structure integrity for the PCB. Such a multi-layer PCB may include a plurality of layers that include a plurality of signal layers, a plurality of ground plane layers, a plurality of inner signal layers, and a single core substrate layer. Each layer in the plurality of layers may be separated from every other layer in the plurality of layers by at least one prepreg substrate layer.