Disclosed is an optical receiver. The optical receiver includes a circuit board, a base member, a photodetector mounted on the base member, a transimpedance amplifier, and a capacitor. The base member is disposed between a first grounding pattern and a second grounding pattern on a first side of the circuit board. The transimpedance amplifier is mounted on the first grounding pattern. The capacitor is mounted on the second grounding pattern. The first wiring pattern and the second wiring pattern are apart from both the first grounding pattern and the second grounding pattern in a plan view of the first side. The first grounding pattern is electrically connected to the second grounding pattern through a grounding pattern formed on the first side.

A signal transmission circuit includes a printed circuit board including a surface layer including a signal transmission path that transmits a signal, a signal line through hole that connects the signal transmission path with a signal layer arranged in an inner layer of the printed circuit board, a ground layer of the inner layer of the printed circuit board that forms a return current transmission path for the signal transmission path, and a ground through hole that is connected to the ground layer adjacent to the signal line through hole. A ground pattern including ground areas disposed with a certain distance therebetween and a side ground area connected with at least one end side of the ground areas is disposed at positions of both sides of the signal transmission path. The ground through hole is disposed to connect the ground pattern with the ground layer.

An electronic circuit, comprising: an integrated substrate structure comprising one or more electrically conductive traces comprising plating on a laser-etched, non-conductive isolated portion of the integrated substrate structure defining each electrically conductive trace; one or more electrically conductive pads at one or more predetermined positions along the one or more electrically conductive traces; and an electrical component surface mounted to the at least one electrically conductive pad with interconnect and bonding material.

A mounting wiring board, containing a base, an electrode portion disposed on the base, and a heat generation pattern disposed on the electrode portion and to be heated by a standing wave of a microwave, in which an occupation area of the heat generation pattern is smaller than an area of an upper surface of the electrode portion; an electronic device mounting board using the mounting wiring board; a method of mounting the electronic device; a microwave heating method, which contains heating an object to be heated provided via the heat generation pattern; and a microwave heating apparatus.

An electronic component mounted body includes a substrate, a connection section provided on the substrate, an electronic component having a terminal connected to the connection section, and a solder that fixes the electronic component to the connection section. The connection section has a first region in which the terminal is fixed through the solder, and a second region lower in wettability than the first region, and the second region has an extension region extended to a peripheral edge of the connection section, and a spaced region that projects from the extension region toward the first region and that is provided to be spaced from the peripheral edge.

A printed circuit structure includes a printed conductive pattern and a printed conductive adhesive pattern. The printed conductive pattern includes a first wire and a second wire. One of a first main contact portion of the first wire and a first main contact portion of a first adhesive of the printed conductive adhesive pattern extends in a first direction, while another thereof extends in a second direction perpendicular to the first direction. With different lengths in the first direction, manufacturing errors between the first wire and the first adhesive in the first direction can be contained without affecting the connection in between. Similarly, a second main contact portion of the second wire and a second main contact portion of a second adhesive of the printed conductive adhesive pattern can also adopt the same design in the first direction to ensure the electric connection.

A novel method and interface are provided to generalize power delivery (PD) solutions and allow OEMs and suppliers to easily replace PD solutions using the same design and layout without having to re-spin the motherboard. This is achieved by defining a new interface and ball-out which support dual port PD solution that meet the system requirements. The embodiments employ an interposer to unify different PD solutions. The interposer is part of a unique Land Grid Array (LGA) soldered down solution with pre-defined interface employing a generic pinout to support PD solutions for dual type-C ports from different vendors. The interposer includes an LGA having a pattern of pads that is coupled to a LGA on a platform PCB with a matching pattern.

A display device includes a display panel, a first circuit board, a control unit disposed on the first circuit board, a second circuit board, and a coupling film which electrically couples the control unit and the second circuit board to each other. The coupling film includes a first coupling part including a first region attached to the first circuit board, and a second region overlapping the display panel when viewed in a thickness direction of the display panel, a second coupling part including a third region attached to the second circuit board, and a fourth region overlapping the display panel when viewed in the thickness direction of the display panel, and a third coupling part coupled to each of the second region and the fourth region to electrically couple the first coupling part and the second coupling part to each other.

A bonding pad such as for a ball grid array includes a conductive pad having a top surface and a first interface surface in contact with a signal trace of a substrate, and a plating layer having a bottom surface in direct contact with the top surface of the conductive pad. The plating layer includes one or more protrusions extending toward the signal trace in a direction generally parallel to a longitudinal axis of the signal trace. Each of the one or more protrusions includes two parallel sidewalls extending upwardly from the bottom surface of the plating layer, and a second interface surface contiguous with the bottom surface of the plating layer. The second interface surface is positioned over and in direct contact with a top surface of the signal trace. The protrusions prevent the connection to the signal trace from being compromised.

A BGA structure having larger solder balls in high stress regions of the array is disclosed. The larger solder balls have higher solder joint reliability (SJR) and as such may be designated critical to function (CTF), whereby the larger solder balls in high stress regions carry input/output signals between a circuit board and a package mounted thereon. The larger solder balls are accommodated by recessing each ball in the package substrate, the circuit board, or both the package substrate and the circuit board. Additionally, a ball attach method for mounting a plurality of solder balls having different average diameters is disclosed.