Disclosed are film packages and methods of fabricating package modules. The film package includes a film substrate that includes a chip region and a peripheral region facing each other in a first direction, a plurality of output pads that are arranged in the first direction on the chip region and on the peripheral region, and a semiconductor chip on the chip region and electrically connected to the output pads. The output pads on the chip region are arranged at regular first intervals along the first direction. The output pads include a plurality of first output pads that are arranged at a first pitch along the first direction on the chip region and a plurality of second output pads on the peripheral region. The second output pads are arranged at a second pitch greater than the first pitch of the first output pads.

A display device includes a substrate including a display area and a non-display area adjacent to the display area, lower pads disposed in the non-display area of the substrate and spaced apart from each other, upper pads disposed on the lower pads and spaced apart from each other, an anisotropic conductive film disposed between the lower pads and the upper pads, and a circuit film disposed on the upper pads, the circuit film including first lower holes disposed between the upper pads in a plan view, and first upper holes connected to the first lower holes and having radiuses larger than radiuses of the first lower holes. The first upper holes form first openings on an upper surface of the circuit film. A method of manufacturing the display device is provided.

A circuit board assembly and electronic device are provided that improve the reliability of the connection between circuit boards and electronic components. The circuit board assembly includes a first circuit board, including a first side surface and a first sidewall pad, where the first sidewall pad is disposed on the first side surface, a second circuit board, fastened to the first circuit board, where the first sidewall pad is located at a position close to the second circuit board, and sidewall solder, adhered to the first sidewall pad and the second circuit board.

Devices including a substrate and a plurality of coil portions disposed on the substrate. The plurality of coil portions electrically coupled to form a coil structure.

A semiconductor module includes a semiconductor device having a first land, a second land, and a third land, a wiring board having a substrate, and a fourth land, a fifth land, and a sixth land disposed on the main surface of the substrate, a chip component having a first electrode and a second electrode disposed across a distance in the longitudinal direction and being disposed between the wiring board and the semiconductor device, a first solder joint for bonding the first land, the fourth land, and the first electrode, a second solder joint for bonding the second land, the fifth land, and the second electrode, and a third solder joint for bonding the third land and the sixth land. The volume of the first solder joint and the volume of the second solder joint are each larger than the volume of the third solder joint.

An electronic component mounting substrate includes an electronic component and a substrate that are electrically connected at a plurality of places on a bottom surface of the electronic component. At least two places of the plurality of places are electrically connected by bonding using a conductive adhesive, and places other than the at least two places of the plurality of places are electrically connected by soldering using a paste solder.

A printed circuit board according to an embodiment includes a first insulating layer, a second insulating layer disposed on the first insulating layer and including a cavity; and a pad disposed on the first insulating layer and having an upper surface exposed through the cavity; wherein the cavity includes a first part including a first inner wall; and a second part including a second inner wall under the first part; and wherein an inclination angle of the first inner wall is different from an inclination angle of the second inner wall.

A signal transmission circuit packaging structure is disclosed. The signal transmission circuit packaging structure includes a body, a main circuit unit, power pins, input pins, output pins, control pins and ground pins. The main circuit unit is arranged in the center of the body. The power pins are arranged in the center of the body. The input pins are arranged at a first side of the body and are electrically connected to the main circuit unit. The output pins are arranged at a side of the body opposite to the first side and are electrically connected to the main circuit unit. The control pins are arranged at a second side of the body and are electrically connected to the main circuit unit. The ground pins are arranged at corners of the body to separate the input pins, the output pins and the control pins.

A blank package for mimicking an electronic component package comprises a body and a plurality of conductive pads. The body is formed from generally transparent electrically insulating material and has a top surface, a bottom surface, and a plurality of side surfaces. The bottom surface has a shape and dimensions that are similar to a bottom surface of the electronic component package. The conductive pads are formed from electrically conductive material and attached to the body, with each conductive pad corresponding to a successive one of the conductive pads of the electronic component package. Each conductive pad has features that are similar to features of the corresponding conductive pad of the electronic component package.

Flexible electrical devices comprising electrode layers on softening polymers and methods of manufacturing such devices, including lift-off processes for forming electrodes on softening polymers, processes for forming devices with a patterned double softening polymer layer, and solder reflow processes for forming electrical contacts on softening polymers.