An electronic component mounting structure is an electronic component mounting structure in which an electronic component group is mounted on a substrate, and a pattern constituting a part of a current path between the inflow port and the outflow port, the electronic component group includes a plurality of electronic components connected between the inflow port and the outflow port, each of the electronic components has a current inflow terminal electrically connected to the inflow port and a current outflow terminal electrically connected to the outflow port, and one of a first spatial distance group and a second spatial distance group has equal spatial distances within the one spatial distance group, and the first spatial distance group includes spatial distances between the inflow port and the inflow terminals, and the second spatial distance group includes spatial distances between the outflow port and the outflow terminals.

An implantable electronic device includes a flexible circuit board, one or more circuit components attached to the flexible circuit board and configured to convert electrical energy into electrical pulses, and one or more electrodes attached to the flexible circuit board without cables connecting the electrodes to each other or to the flexible circuit board, the one or more electrodes configured to apply the electrical pulses to a tissue adjacent the implantable electronic device.

A light-emitting diode (LED) package includes a package substrate, an LED chip disposed on a first surface of the package substrate, and a first external connection pad and a second external connection pad disposed on a second surface of the package substrate opposite the first surface. The first external connection pad includes a first side, a second side, a third side and a fourth side, the first side being parallel to the second side, and the third side being parallel to the fourth side. The first side is spaced farther from a center of the package substrate than the second side. A length of the first side is shorter than a length of the second side.

A substrate conductive bonding structure includes a lower substrate including a connection pad exposed to outside the lower substrate, an upper substrate including a transfer pad overlapping the connection pad, exposed to outside the upper substrate and including an upper surface, and a slit defined in the transfer pad, overlapping the connection pad and open at the upper surface of the transfer pad, the slit including an extending portion extending along a first direction and having a first slit width along a second direction crossing the first direction, and an expansion portion connected to the extending portion and having a second slit width along the second direction which is larger than the first slit width, and a solder contacting the upper surface of the connection pad, extending to the upper surface of the transfer pad and into the slit.

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 is provided. The substrate includes a bottom plate and at least one bonding portion disposed on the bottom plate, where each bonding portion takes a shape that is a part of an Archimedean spiral. An electronic device, a bonding structure, and a bonding method for the bonding structure are further provided.

An interconnection for flex circuit boards used, for instance, in a quantum computing system are provided. In one example, the interconnection can include a first flex circuit board having a first side and a second side opposite the first side. The interconnection can include a second flex circuit board having a third side and a fourth side opposite the third side. The first flex circuit board and the second flex circuit board are physically coupled together in an overlap joint in which a portion of the second side for the first flex circuit board overlaps a portion of the third side of the flex circuit board. The interconnection can include a signal pad structure positioned in the overlap joint that electrically couples a first via in the first flex circuit board and a second via in the second flex circuit board.

A printed circuit board includes: a base substrate including a unit region; a plurality of connection pads disposed on one surface of the base substrate; and first and second lead-in lines disposed on the one surface and respectively connected to at least a portion of the plurality of connection pads. The first and second lead-in lines have first and second cut surfaces on the one surface, respectively. The first cut surface is disposed in a position spaced apart from a side surface of the printed circuit board. The second cut surface is exposed to the side surface of the printed circuit board.

A package carrier includes a build-up circuit structure, a first insulation protective layer, a plurality of connection pads, and a plurality of metal balls. The build-up circuit structure has an upper surface. The first insulation protective layer is disposed on the upper surface of the build-up circuit structure and has a plurality of first openings. The connection pads are respectively disposed in the first openings of the first insulation protective layer and are structurally and electrically connected to the build-up circuit structure. Each of the connection pads has an arc-shaped groove. The metal balls are respectively disposed in the arc-shaped groove of the connection pads. The metal balls and the corresponding connection pads define a plurality of bump structures, and a plurality of top surfaces of the bump structures are on a same plane.

An optical integration device includes a first circuit layer comprising a first surface adjacent a first diffractive layer, the first diffractive layer arranged on a side of the first circuit layer along a first direction, and a first connecting pad electrically connected with the first circuit layer through a first conductive member. The optical integration device includes a side surface extending along the first direction. The side surface defines a first concavity extending through the first diffractive layer along the first direction. The first connecting pad includes a first mounting member connected with the side surface, and a first convex member extending from the first mounting member and received in the first concavity. The first conductive member includes a first conductive part arranged between the side surface and the first mounting member, and a second conductive part arranged between the first surface and the first convex member.