A film type package includes: a base film having first and second sides; a driver integrated circuit mounted on the base film; first connection pads disposed on a first area of the base film that is adjacent to the first side of the base film, and configured to be connected to a first external circuit; second connection pads disposed on a second area of the base film that is adjacent to the second side of the base film, and configured to be connected to a second external circuit; first signal lines disposed on the base film, and connecting the driver integrated circuit and the first connection pads; second signal lines disposed on the base film, and connecting the driver integrated circuit and the second connection pads; and a plurality of test lines extending from the driver integrated circuit to the first side of the base film.

A sensor lens assembly having a non-reflow configuration is provided. The sensor lens assembly includes a circuit board, an electronic chip assembled to the circuit board, a sensor chip, a die attach film (DAF) pre-bonded onto the sensor chip, a plurality of wires electrically coupling the electronic chip and the sensor chip to the circuit board, a supporting adhesive layer, a light-permeable sheet, and an optical module that is fixed to the circuit board for surrounding the above components. The sensor chip is adhered to the electronic chip through the DAF such that a sensing region of the sensor chip is perpendicular to a central axis of the optical module. The supporting adhesive layer is in a ringed shape and is disposed on a top surface of the sensor chip. The light-permeable sheet is disposed on the supporting adhesive layer and faces the sensor chip.

Methods and systems for fabricating 3D electronic devices, such as multielectrode arrays, including metalized, 3D printed structures using integrated 3D printing and photolithography techniques are disclosed. As one embodiment, a multielectrode array comprises a flexible substrate, a plurality of photopatterned electrical traces spaced apart and insulated from one another on the substrate, and a plurality of 3D printed electrodes. Each 3D printed electrode comprises a photopolymer coated in metal and has a 3D structure that extends outward from the substrate, and each 3D printed electrode is electrically connected to a corresponding electrical trace of the plurality of photopatterned electrical traces.

A component includes a plurality of electrical connections on a process side opposed to a back side of the component. Each electrical connection includes an electrically conductive multi-layer connection post protruding from the process side. A printed structure includes a destination substrate and one or more components. The destination substrate has two or more electrical contacts and each connection post is in contact with, extends into, or extends through an electrical contact of the destination substrate to electrically connect the electrical contacts to the connection posts. The connection posts or electrical contacts are deformed. Two or more connection posts can be electrically connected to a common electrical contact.

A light emitting device filament includes a substrate, a plurality of light emitting diodes, two electrode pads, and a plurality of connection lines. The substrate includes a first surface and a second surface opposite to the first surface. The substrate extending in a first direction and having a width in a second direction. The plurality of light emitting diodes is disposed on the first surface of the substrate. The two electrode pads are disposed on the substrate. The plurality of connection lines electrically connects the plurality of light emitting diodes and the two electrode pads. The plurality of connection lines includes a first connection line and a second connection line. The first connection line, the second connection line, or both are formed in a direction inclined or curved with respect to the first direction or the second direction.

A multilayer circuit board includes an upper surface and an opposing lower surface. An electrically insulating layer is disposed between the upper and lower surfaces. A plurality of electrically conductive upper and lower rear pads are disposed proximate a rear edge on the respective upper and lower surfaces for termination of a plurality of wires. The upper and lower rear pads include respective upper and lower rear ground pads substantially aligned with each other and configured for termination of ground wires. A plurality of electrically conductive front pads are disposed proximate a front edge for insertion into a connector and electrically connected to the upper and lower rear pads. An electrically conductive via extends from the upper rear ground pad to the lower rear ground pad and makes electrical and physical contact with each of the upper and lower rear ground pads.

A flexible circuit board for transmitting a signal in a frequency band includes an intermediate region in which a signal line is disposed as a transmission line for transmitting the signal in the frequency band, and a pad region extending from the intermediate region and disposed at one end or both ends of the flexible circuit board, a pad electrically connected to the signal line and formed to face a first direction of the flexible circuit board, and a ground pattern overlapping at least a portion of the pad and formed to face a second direction of the flexible circuit board and disposed in the pad region where the second direction is opposite to the first direction.

Connector paddle cards are provided with an improved wiring connection geometry that reduces impedance mismatch. One illustrative embodiment is a printed circuit board having, on at least one surface: edge connector traces arranged along a first edge for contacting electrical conductors in a socket connector; an outer set of electrodes arranged parallel to a second edge for attaching exposed ends of sheathed wires in a cable (“outer wires”); and an inner set of electrodes arranged parallel to the second edge for attaching exposed ends of sheathed wires in a cable (“inner wires”), with the electrodes in the inner set being staggered relative to the electrodes in the outer set.

According to examples, a memory module with module rows of conductive contacts can enable multiple memory channels to be connected to the same memory module. In one example, a memory module includes a printed circuit board (PCB) having a first face, a second face, and an edge to be received by a connector. The memory module includes a plurality of memory chips on at least one of the first and second faces of the PCB. The memory module includes two or more rows of conductive contacts on each of the first and second faces of the PCB, the two rows including a first row of conductive contacts proximate to the edge of the PCB to be received by the connector, and a second row of conductive contacts between the first row and a second edge of the PCB opposite to the first edge.

A wiring module according to an embodiment of the present technology includes: a wiring board and a heat dissipation member. The wiring board includes a body portion and one or more heat dissipation vias, the body portion including a front surface layer to which a device package is connected and a rear surface layer opposite to the front surface layer, the one or more heat dissipation vias penetrating the body portion from the front surface layer to the rear surface layer. The heat dissipation member is connected to the rear surface layer so as to thermally bond with the one or more heat dissipation vias.