An RF crossover apparatus provides low transmission and return losses for microwave systems and meets the requirement for the RF signals to leap over each other as in an insulated state. The RF crossover apparatus contains a body produced from ceramic material, at least two RF strips placed inside the body in a way to intersect each other and at least one insulation layer insulating the RF strips placed on the body at least from the external environment. The body produced from ceramic material enables operation on high frequencies and this provides low transmission and return losses. The RE crossover apparatus also contains matching circuits on the tips of the RF strips for the RF strips to be passed to chip devices during use.

The present disclosure relates to a telecommunications jack including a housing having a port for receiving a plug. The jack also includes a plurality of contact springs adapted to make electrical contact with the plug when the plug is inserted into the port of the housing, and a plurality of wire termination contacts for terminating wires to the jack. The jack further includes a circuit board that electrically connects the contact springs to the wire termination contacts. The circuit board includes a multi-zone crosstalk compensation arrangement for reducing crosstalk at the jack.

A movable embedded microstructure includes a substrate, a diaphragm, a circuit board, a permanent magnetic element, and a multi-layered coil. The substrate has a hollow chamber. The diaphragm is disposed on the substrate, and covers the hollow chamber. The circuit board is bonded to the substrate. The permanent magnetic element is disposed on the circuit board and in the hollow chamber. The multi-layered coil is embedded in the diaphragm.

One innovative aspect of the subject matter described in this disclosure can be implemented in a wireless power reception apparatus. In some implementations, the wireless power reception apparatus may include a ferrite layer including a void. The wireless power reception apparatus may also include a first secondary coil configured to generate first power in cooperation with one or more primary coils of a wireless power transmission apparatus, where at least a portion of the first secondary coil resides in the void of the ferrite layer. The wireless power reception apparatus may also include one or more second secondary coils configured to generate second power in cooperation with the one or more primary coils of the wireless power transmission apparatus, where a portion of the second secondary coil is overlaying the portion of the first secondary coil residing in the void of the ferrite layer.

The present invention is directed to flexible conductive articles (600) that include a printed circuit (650) and a stretchable or non-stretchable substrate (610). In some embodiments, the substrate has a printed circuit on both sides. The printed circuit contains N therein a porous synthetic polymer membrane (660) and an electrically conductive trace (670) as well as a non-conducive region (640). The electrically conductive trace is imbibed or otherwise incorporated into the porous synthetic polymer membrane. In some embodiments, the synthetic polymer membrane is microporous. The printed circuit may be discontinuously bonded to the stretchable or non-stretchable substrate by adhesive dots (620). The printed circuits may be integrated into garments, such as smart apparel or other wearable technology.

A display device includes a display panel, and an electrostatic capacitive type touch panel which is formed in an overlapping manner with the display panel. A plurality of X electrodes and a plurality of Y electrodes intersecting with the X electrodes. A first signal line supplies signals to the X electrodes, a second signal line supplies signals to the Y electrodes, and the first signal line and the second signal line are formed on a flexible printed circuit board. A dummy electrode is formed adjacent to an electrode portion of each X electrode and electrode portion of each Y electrode, the dummy electrode does not overlap the X electrode and the Y electrode, and the dummy electrode does not electrically connect with the first and second signal lines.

A wiring structure of a head suspension including a flexure that supports a head and is attached to a load beam applying load onto the head, includes write wiring and read wiring formed on the flexure and connected to the head, each having wires of opposite polarities and further including a stacked interleaved part which includes segments electrically connected to the respective wires of the write wiring, the segments stacked on and facing the wires through an electrical insulating layer so that the facing wire and segment have opposite polarities, is manufactured by a wiring step, an insulating layer forming step and a stacked interleaved part forming step.

This disclosure provides a stretchable conductor structure, a garment with a stretchable conductor structure, and a method for producing a stretchable conductor structure. The conductive structure includes a set of conductive wires and a stretchable laminate. The set of conductive wires, each including a protective surface, the set of conductive wires patterned in a mesh structure to accommodate a manipulation while providing electrical conductivity across the set of conductive wires. The stretchable laminate encapsulates the mesh structure, the stretchable laminate can return the mesh structure of the set of conductive wires to an original state after the manipulation.

An electrical interconnection system for electrical components of a module includes a hub printed circuit board (PCB) having a first electrically conductive track and a second electrically conductive track. Each of the first and second electrically conductive tracks is configured to electrically connect at least two of the electrical components of the module, wherein the at least two of the electrical components of the module are external to the hub PCB. The system also includes multiple electrical terminals, wherein each of the electrical terminals is configured to electrically connect one of the first and second electrically conductive tracks of the hub PCB to one of the at least two electrical components of the module.

A flexible display panel and a display device are provided. The flexible display panel includes a bent portion. The bent portion includes a substrate layer group and a conductive wire group. The conductive wire group is located on the substrate layer group. The conductive wire group includes a plurality of conductive wires in a curved shape. At least two of the plurality of conductive wires cross and surround at least one closed region. The at least one closed region is provided at least corresponding to a bent region of the bent portion.