An electronic device and associated methods are disclosed. In one example, the electronic device can include an assembly having asymmetrically situated conductors. In selected examples, the assembly includes a ground plane, a central shield portion, a first side shield portion on a first side, a second side shield portion on a second side, a first conductor asymmetrically situated between the central shield portion and the first side shield portion, a second conductor asymmetrically situated between the central shield portion and the second side shield portion, and dielectric within the assembly.

A component carrier has a laminated stack including at least one electrically conductive layer structure and/or at least one electrically insulating layer structure, a front-end chip on and/or in the stack and extending at least up to a main surface of the stack, an antenna interface on an opposing other main surface of the stack, and an impedance matching circuitry in the stack and arranged vertically between the front-end chip and the antenna interface.

A circuit board with a connector connection for the direct contacting with a connector, wherein the connector connection is formed on the front side of the circuit board with a contact pin that is arranged centrally in a blind hole while forming a circular ring-shaped cylindrical insertion space and that has an inner hole with a first contact zone of an inner conductor for contacting an inner conductor of the connector. A second contact zone of an outer conductor is arranged in the insertion space for contacting an outer conductor of the connector.

A flexible circuit (FC) comprises a primary dielectric layer having a plurality of substantially parallel conductive circuit traces disposed therein and a secondary dielectric layer extending from or attached to the primary dielectric layer, wherein the secondary dielectric layer does not have any conductive circuit traces disposed therein, and wherein at least one of the primary and secondary dielectric layers defines an alignment feature for wrapping and securing the FC about a central structure. A method of wrapping and securing the FC about a central stricture comprises wrapping the FC about the central structure while aligning each alignment feature with a respective complimentary alignment feature such that the FC fully encompasses the central structure and is secured thereabout.

A connector includes a flexible connector having a first plurality of solder bumps arranged in a first pattern, and a base connector having a second plurality of solder bumps arranged in a second pattern concentric with and of a different size than the first pattern. A method of interconnecting a flexible connector to a base connector includes providing the flexible connector with a first plurality of solder bumps arranged in a first pattern, and providing the base connector with a second plurality of solder bumps arranged in a second pattern. The flexible and base connectors are aligned by aligning the first and second pluralities of solder bumps.

An example printed circuit board (PCB) includes a substrate having layers of a dielectric material, where the layers of dielectric material include a first layer and a second layer; a conductive trace that is between the first layer and the second layer and that is parallel to the first layer and the second layer along at least part of a length of the conductive trace; and a conductive via that extends at least part-way through the layers of dielectric material and that connects electrically to the conductive trace, where the conductive via is configured also to connect electrically to a signal input to receive or to transmit a signal that has a center frequency span.

A wiring board includes a wiring board body and a coaxial connector. The coaxial connector includes coaxial terminals and a housing. The coaxial terminals are arranged in row. Each of the coaxial terminals includes a signal terminal and a ground terminal. The ground terminal includes a tubular main body and first and second contact pieces that respectively extend from the main body and respectively include first and second contact portions in contact with the wiring board body, in a transparent plan view seen through the wiring board along a normal direction of the wiring board body. A part of the first contact piece of a first coaxial terminal overlaps with a part of the second contact piece of a second coaxial terminal adjacent to the first coaxial terminal.

A method for controlling a target switch assembly in a chain of switch assemblies includes distributing the chain of switch assemblies in a wellbore; placing a controller at a head of the wellbore; making a first decision, at the controller, to actuate a corresponding detonator of the target switch assembly; transmitting, from the controller to the target switch assembly, a fire command to activate the corresponding detonator; and making a second decision, locally, at the target switch assembly, to activate the detonator, after the fire command from the controller is received.

A substrate includes, two first through-holes to which high-frequency signals are transmitted and which are arranged side by side so as to have a predetermined distance, and at least three reference potential second through-holes arranged side by side so as to have an distance smaller than the predetermined distance with respect to the two first through-holes. Among three of the second through-holes, one of the second through-holes is arranged in a region between the two first through-holes, and other two of the second through-holes are arranged in a region other than the region between the first through-holes such that one of the other two second through-holes is arranged side by side with respect to one of the two first through-holes, and the other of other two second through-holes is arranged side by side with respect to the other of the two first through-holes.

An electronic device may be provided with a transceiver, a substrate, and antennas mounted to the substrate. The transceiver and antennas may convey signals between 10 GHz and 300 GHz. A radio-frequency connector may be mounted to the substrate. A coaxial cable may couple the transceiver to the connector. A stripline in the substrate may couple the connector to the antennas. Impedance matching structures may be embedded in the substrate for matching an impedance of the stripline to an impedance of the coaxial cable. The impedance matching structures may include a fence of conductive vias, landing pads, and a volume of the dielectric substrate defined by the fence of conductive vias and the landing pads. The impedance matching structures may be configured to perform impedance matching over a relatively wide bandwidth that includes the frequency band of operation for the antennas.