A metal foil layer includes a metal foil layer upper main surface, a metal foil layer lower main surface with a surface roughness greater than that of the metal foil layer upper main surface, and a metal foil layer side surface that is a surface of the metal foil layer excluding the metal foil layer upper main surface and the metal foil layer lower main surface. The metal foil layer upper main surface is in contact with an upper resin layer. The metal foil layer lower main surface is in contact with a lower resin layer. A portion of a lower main surface of the upper resin layer and a portion of an upper main surface of the lower resin layer are in contact with each other to define a layer interface. In a cross section of the metal foil layer, the metal foil layer side surface includes an outer point and an inner point where the upper resin layer is in contact with the side surface, and the inner point is below the outer point and inward of the outer point.

A heat radiating substrate (10) includes an insulating layer (11) and a circuit pattern (20) of a metal formed on the insulating layer (11) in direct contact with the insulating layer (11), in which a side surface (that is, metal layer side surface (23)) of the circuit pattern (20) has a region in which an angle θ formed by a surface (insulating layer upper surface (11a)) of the insulating layer (11) (insulating substrate) and a tangential line L at a middle portion (X1) in a height direction in a cross-sectional view perpendicular to an extending direction of the metal is 80 degrees or more and 100 degrees or less.

A circuit board includes a first section on a left side of a third section in a signal-conductor-layer left-right direction and extending in parallel or substantially in parallel with the third section in a signal-conductor-layer front-back direction when viewed in a stacking direction. The first section includes first thin line portions and first thick line portions, each of the first thick line portions has a line width greater than a line width of each of the first thin line portions. The first thin line portions and the first thick line portions are alternately arranged in the signal-conductor-layer front-back direction. In the signal-conductor-layer left-right direction, center lines of the first thin line portions are positioned leftward relative to center lines of the first thick line portions.

A device includes a printed circuit board substrate, an antenna connected to the printed circuit board substrate, an amplifier connected to the printed circuit board substrate, and a matching track having a first end electrically connected to an input of the amplifier and a second end electrically connected to an output of the antenna. The matching track has an outgrowth that is symmetrical along a median axis of the outgrowth. The matching track is rectilinear and has a constant width over an initial part extending between the widening area and the first end. A median axis of the initial part and the median axis of the outgrowth form an angle comprised between 60 and 120°.

A high-current contact device includes a first contact element transmitting electrical energy, a circuit carrier, a first data contact transmitting data, and a data interface. The first contact element extends through the circuit carrier along a mating axis at a feedthrough. A conductor track of the circuit carrier electrically connects the first data contact to the data interface. A carrier of the circuit carrier is injection-molded and mechanically supports the first data contact, the conductor track, and the data interface.

A high-frequency device includes: a circuit substrate including dielectric layers that are stacked, wiring patterns located on at least one of the dielectric layers, and a passive element formed of at least one of the wiring patterns, the circuit substrate having a first surface that is a surface of an outermost dielectric layer in a stacking direction of the dielectric layers; a terminal for connecting the high-frequency device to an external circuit, the terminal being located on the first surface and electrically connected to the passive element through a first path in the circuit substrate; and an acoustic wave element located on the first surface and electrically connected to the passive element through a second path in the circuit substrate.

A printed circuit board (PCB) comprises two or more PCB layers comprising of a dielectric core and conductive cladding on adjoining surfaces; one or more DC lines embedded in one or more layers of the two or more PCB layers; one or more RF signal lines embedded in one or more layers of the two or more PCB layers; wherein the one or more DC lines crosses over/under at least one of the RF signal lines to form at least one crossover, wherein the at least one crossover is no thicker than the PCB layer in which it is situated. The printed circuit board of claim 1, further comprising two or more generally parallel DC lines which converge to form a stack of superposed parallel DC lines where the two or more DC lines cross over the one or more RF signal lines.

An exemplary bridging inter-connector establishes electrical connections between conductors on a PCB and aligned conductors on a first board mounted to the PCB. A flexible non-conductive sheet covers at least a portion of these conductors. Separated conductive strips on the sheet that are dimensioned to align with and engage at least a portion of both the aligned conductors. A thin film of a bonding agent is disposed on the separated conductive strips and located to engage at least a portion of both aligned conductors to form a conductive connection.

In one embodiment, a system includes a ground layer, a first layer, a second layer, and a plurality of vias. The first layer includes a first insulating material and a plurality of first metallic strips. The second layer includes a second insulating material and a plurality of second metallic strips. The plurality of vias electrically connect one or more of the plurality of first metallic strips of the first layer to one or more of the plurality of second metallic strips of the second layer. The plurality of first metallic strips of the first layer and the plurality of second metallic strips of the second layer form a plurality of capacitors and a plurality of conductors. Each capacitor is located in the first layer. Each conductor is partially located in the first layer and partially located in the second layer.

A high-current contact device includes a first contact element transmitting electrical energy, a circuit carrier, a first data contact transmitting data, and a data interface. The first contact element extends through the circuit carrier along a mating axis at a feedthrough. A conductor track of the circuit carrier electrically connects the first data contact to the data interface. A carrier of the circuit carrier is injection-molded and mechanically supports the first data contact, the conductor track, and the data interface.