A printed circuit board and a method of manufacturing the same are provided. The printed circuit board includes a wiring substrate including a plurality of insulating layers, a plurality of wiring layers, and a plurality of via layers and having a cavity penetrating through a portion of the plurality of insulating layers, a passive component disposed in the cavity and including an external electrode electrically connected to at least one of the plurality of wiring layers, and a bridge disposed on the passive component in the cavity and including one or more circuit layers electrically connected to the external electrode.

A semiconductor package includes at least one die attach pad of a leadframe, at least one semiconductor die mounted on the at least one die attach pad; and a plurality of lead terminals disposed around the at least one die attach pad and electrically connected to respective input/output (I/O) pads on the at least one semiconductor die through a plurality of bond wires. The plurality of lead terminals comprises first lead terminals, second lead terminals, and third lead terminals, which are arranged in triple row configuration along at least one side of the semiconductor package. Each of the first lead terminals, second lead terminals, and third lead terminals has an exposed base metal on a cut end thereof.

An interposer includes an interposer body; first and second lower patterns spaced apart from each other on a lower surface of the interposer body; and first and second upper patterns spaced apart from each other on an upper surface of the interposer body. The first and second upper patterns include first and second shape-securing layers spaced apart from each other on the upper surface of the interposer body, and first and second acoustic noise reduction layers disposed on the first and second shape-securing layers, respectively. An electronic component includes a capacitor and the interposer.

A printed circuit board includes a first chip component, a second chip component, and a printed wiring board. The first chip component and the second chip component each has a length L2 in the longitudinal direction. A relationship of 0.894≤L2/L1≤1.120 is satisfied, where L1 represents a length of the first opening in the longitudinal direction. A relationship of 0.894≤L2/4≤1.120 is satisfied, where length L4 represents a length of the second opening in the longitudinal direction. A relationship of 0.183≤L.sub.OA/L.sub.iA≤50.309 is satisfied, where L.sub.iA represents a length of the first land in the longitudinal direction, and L.sub.OA represents a thickness of solder on an end surface of the first electrode. A relationship of 0.183≤L.sub.OB/L.sub.iB≤0.309 is satisfied, where L.sub.iB represents a length of the second land in the longitudinal direction, and L.sub.OB represents a thickness of solder on an end surface of the second electrode.

A composite electronic component composed of a composite body including a capacitor and an electrostatic discharge (ESD) protection device coupled to each other. The capacitor includes a ceramic body in which a plurality of dielectric layers and internal electrodes are stacked with a respective dielectric layer therebetween. The ESD protection device includes first and second electrodes disposed on the ceramic body, a discharging part disposed between the first and second electrodes, and a protective layer disposed on the first and second electrodes and the discharging part. An input terminal disposed on a first end surface of the composite body and is connected to internal electrodes and the first and second electrodes. A ground terminal formed on a second end surface of the composite body and is connected to internal electrodes and the first and second electrodes.

The described embodiments relate generally to printed circuit boards (PCBs) including a capacitor and more specifically to designs for mechanically isolating the capacitor from the PCB to reduce an acoustic noise produced when the capacitor imparts a piezoelectric force on the PCB. Conductive features can be mechanically and electrically coupled to electrodes located on two ends of the capacitor. The conductive features can be placed in corners where the amplitude of vibrations created by the piezoelectric forces is relatively small. The conductive features can then be soldered to a land pattern on the PCB to form a mechanical and electrical connection while reducing an amount of vibrational energy transferred from the capacitor to the PCB.

An electrical component, such as an RF device or thermal bridge, for use with a printed circuit board. The component has a first dielectric layer having a top and a bottom, a first conductive trace positioned on the bottom of the dielectric layer, and a first ground layer positioned on the bottom of the dielectric layer and spaced apart from the first conductive trace. For RF applications, a second conductive trace is positioned on top of first dielectric, a second dielectric is positioned on top of the second conductive trace, and a second ground plane is positioned on top of the second dielectric. A printed circuit board having a third conductive trace may then be coupled to the first conductive trace by a first solder layer.

A method of producing electronic components each including a substrate-type terminal and a device connected to the substrate-type terminal is performed such that the substrate-type terminal includes a substrate body including a rectangular or substantially rectangular first principal surface extending in first and second directions perpendicular or substantially perpendicular to each other. The device is disposed on the first principal surface. The method includes supporting a substrate that is to become an assembly in which the plurality of substrate-type terminals are arranged in a matrix using a first support member, cutting the substrate supported by the first support member into the plurality of substrate-type terminals, and mounting the device on the first principal surface of the substrate body of each of the plurality of substrate-type terminals obtained by cutting.

A multilayer-ceramic-capacitor mounting structure includes a circuit board and a multilayer ceramic capacitor. First and second external electrodes include first and second conductive resin layers on surfaces of first and second base electrode layers, respectively. The circuit board includes a copper plate on a surface of a core, disposed as a wiring pattern, and including a predetermined thickness, and signal electrodes disposed on a surface of the copper plate. The first and second external electrodes are each electrically connected to the signal electrodes of the copper plate.

A fabric-based item may include fabric formed from intertwined strands of material. The fabric may include first and second fabric layers that at least partially surround a pocket. Initially, the pocket may be completely enclosed by the first and second layers of fabric. A shim may be placed in the pocket before the pocket is closed. An opening may be formed in the first layer of fabric to expose a conductive strand in the pocket. The shim may prevent the cutting tool from cutting all the way through to the second layer of fabric. After cutting the hole in the first layer of fabric, the shim may be removed and an electrical component may be soldered to the conductive strand in the pocket. A polymer material may be injected into the pocket to encapsulate the electrical component. The polymer material may interlock with the surrounding pocket walls.