A group of contact pads (20EB) formed on a lower surface (20B) at a connection end of a board portion of an optical module board (20) includes, in order from the endmost end, a contact pad (20B1) conducting to a ground line (G), contact pads (20B2) and (20B3) conducting to transmission-side high-speed signal lines (S), a contact pad (20B4) conducting to the ground line (G), contact pads (20B5, 20B6, and 20B7) conducting to low-speed signal lines (S), a contact pad (20B8) conducting to the ground line (G), contact pads (20B9 and 20B10) conducting to receiving-side high-speed signal lines (S), and a contact pad (20B11) conducting to the ground line (G). Fixed terminal portions of a plurality of contact terminals (32ai) connected to the contact pads (20B2 and 20B3) conducting to the transmission-side high-speed signal lines (S) and the contact pads (20B9 and 20B10) conducting to the receiving-side high-speed signal lines (S) in a host connector (30) are electrically connected to conductive paths (16THL, 16RHL), which are continuous with high-speed signal lines formed on a plane shared with electrode portions (16BE2, 16BE3, 16BE9, and 16BE10) via the electrode portions (16BE2, 16BE3, 16BE9, and 16BE10) of a printed wiring board (16).

This application provides an optical module, and relates to the field of optical communication. An optical module provided in the embodiments of this application includes a laser box and a silicon photonic chip that are enclosed and packaged by an upper enclosure part and a lower enclosure part. The laser box is disposed on and is in contact with the surface of the silicon photonic chip by the side wall or the base. The laser chip is disposed on the top plane of the laser box. The top plane is in contact with the upper enclosure part for heat dissipation, so as to help heat generated by the laser chip be conducted to the upper enclosure part via the top plane, so that the heat generated by the laser chip is dissipated not via the silicon photonic chip.

A printed circuit board has a solder joint inspection system including a substrate surface having at least one solder pad thereon, at least one conductor wire having an end attached to the at least one solder pad, and a first inspection feature. A first inspection feature is marked on the substrate surface adjacent to the at least one solder pad to define a conductor end zone on the at least one solder pad. The end of the conductor wire is in the conductor end zone when properly attached. The at least one solder pad may define a second inspection feature to mark an extent to which the at least one solder pad is covered by a flow of solder when the wire is properly attached.

A seat plate assembly for fixing a capacitor on a circuit board, including a base plate, a first guard plate, a second guard plate, a third guard plate, a fourth guard plate, a first reinforcing rib and a second reinforcing rib. The first guard plate, the second guard plate, the third guard plate and the fourth guard plate are provided spaced apart on an upper end surface of the base plate in sequence. The first reinforcing rib is configured to connect the first guard plate with the second guard plate. The second reinforcing rib is configured to connect the third guard plate with the fourth guard plate.

A connector includes lead parts and terminal parts to be connected to lands of a substrate, respectively. An anisotropic conductive joining member (ACJM) is mounted in a region where the lead parts are located. The ACJM is a resin in which solder particles are dispersed. The resin can melt at a temperature lower than the melting point of the solder particles. Cream solder is placed on the lands to be connected to the terminal parts. The substrate on which the connector is mounted is passed through a reflow oven to heat both the substrate and the connector. The connection between the terminal parts and the lands by reflow soldering and the connection between the lead parts and the lands via the ACJM 40 are performed simultaneously with each other.

A sensor module includes a circuit board, a sensor element having a detection axis along a planar direction of the circuit board, a sensor package accommodating the sensor element and mounted on the circuit board, a board land pattern used for mounting the sensor package disposed on the circuit board, and a package electrode disposed on a mounting surface of the sensor package facing the circuit board and joined to the board land pattern by a solder. A relationship of Xp≤X1 is satisfied, in which Xp is a width of the board land pattern in a first direction along the planar direction of the circuit board, and X1 is a width of the package electrode in the first direction.

A circuit board and package assembly electrically connecting a die to a circuit board. The circuit board has signal paths terminating in a signal pad located on an insulating layer. The circuit board also includes a ground pad on the insulating layer that has a concave shaped side forming a recess, the with a signal pad at least partially within the recess. A package has package ground pads aligned with the circuit board ground pads and package signal pads aligned with circuit board signal pads. The package ground pads extend through the package to connect to package ground paths, which extend toward the die. The package signal pads extend through the package to connect to package signal paths and the package signal paths extend toward the die, maintaining a consistent distance from the package ground paths. Multiple-tier bond wires connect the package bond locations to the die bond pads.

An electronic device includes at least two boards and support pillars. The at least two boards include hole portions. The support pillars inserted into the hole portions such that the at least two boards are held mutually separated. The hole portions include tapered surfaces that incline toward center portions of the hole portions from a surface on a side from which the support pillars of the boards are inserted.

A reflowable grid array (RGA) interposer includes first connection pads on a first surface of a body and second connection pads on a second surface of the body. Heating elements within the body are adjacent to the second connection pads. First interconnects within the body connect some of the second connection pads to the first connection pads. Second interconnects within the body connect pairs of the second connection pads. A motherboard assembly includes first and second components (e.g., CPU with co-processor and/or memory) and the RGA interposer. The first connection pads are in contact with motherboard contacts. The second connection pads are in contact with the first and second components. The first component passes signals directly to the motherboard by the first interconnects. The second component passes signals directly to the first component by the second interconnects but does not pass signals directly to the motherboard by the first interconnects.

Provided are a circuit assembly in which it is possible to eliminate or reduce a level difference between a mounting surface of a substrate and portions to which terminals that are electrically connected to a conductive member are connected, and that can be easily produced, and a method for manufacturing the same. A circuit assembly includes a substrate provided with openings and an electronic component mounted on one side of the substrate, a conductive member that is a plate-shaped member fixed to another side of the substrate, the conductive member constituting a conductive path, and a relay member that is fixed to a surface on the substrate side of the conductive member and made of an electrically conductive material, the relay member being accommodated in the openings formed in the substrate, at least one terminal of the electronic component being connected to the relay member.