There is provided a control circuit board including a board, an integrated circuit, and a pad group. The board includes a first surface and a second surface, where the first surface and the second surface are on opposite sides of the board. The integrated circuit is disposed on the first surface of the board. The pad group is disposed on the second surface of the board and is electrically connected to the integrated circuit through a through-hole formed in the board.

A soft neural interface connector apparatus includes a PCB having a two-dimensional array of solder balls, a transparent top board, a cushioning layer on one side of the transparent top board, and a soft neural interface including a flexible and/or stretchable microelectrode array (MEA) through which neural signals are obtained or delivered. The MEA includes a two-dimensional array of contact pads corresponding to the array of solder balls. The PCB, the transparent top board, the cushioning layer, and the MEA are stacked together such that the MEA is between the cushioning layer and the PCB, and the contact pads are aligned with and in electrical contact with associated solder balls. A magnetic connector system having at least one magnetic connector component on the transparent top board is magnetically connected with at least one magnetic connector component on the PCB to press the contact pads and associated solder balls together.

An electronic device is disclosed. An electronic device according to an embodiment may include: a first Printed Circuit Board (PCB), a second PCB, a Radio Frequency (RF) transceiver disposed on the first PCB, a Flexible Printed Circuit Board (FPCB) coupled with the first PCB and the second PCB and electrically coupled with the RF transceiver, the FPCB including a transmission line of a wireless communication signal, an amplifier disposed on the second PCB and electrically coupled with the RF transceiver by the FPCB, a first antenna electrically coupled with the amplifier through the second PCB and configured to receive a wireless communication signal corresponding to a first frequency, and a second antenna electrically coupled with the amplifier through the second PCB and configured to receive a wireless communication signal corresponding to a second frequency. The first antenna and the second antenna may be disposed closer to the second PCB than the first PCB in the electronic device. The amplifier may amplify a wireless communication signal received from the first antenna and second antenna.

A flexible display device includes a flexible display panel and a chip on film (COF) bonded to the flexible display panel; wherein the flexible display panel is divided into a display region, a bonding region on a side of the display region, and a bending region between the display region and the bonding region; wherein the COF comprises a main body portion and two expansion bonding portions respectively disposed at two ends of one side of the main body portion; wherein an edge of the main body portion adjacent to the two expansion bonding portions are disposed with a plurality of connection pins; wherein the COF is bonded to the bonding region of the flexible display panel through the plurality of connection pins.

Glucose monitoring devices and related systems and methods, the glucose monitoring devices including a sensor electronics unit having a housing and a printed circuit board disposed within the housing, a transcutaneous glucose sensor assembly, and a conductive sensor connector. The printed circuit board includes a first electrical contact, the transcutaneous glucose sensor assembly includes a distal portion having a working electrode and proximal portion having a working-electrode contact in electrical communication with the working electrode, and the conductive sensor connector electrically connects the working-electrode contact with the first electrical contact. Further, the conductive sensor connector extends through a hole in the proximal portion of the transcutaneous glucose sensor assembly and through a hole in the printed circuit board.

A method for producing a camera module having a first part, preferably a housing part, and a second part, preferably a circuit board or a cover part, in which the two parts are connected in positive locking fashion. The positive lock is produced in that a connecting element connected to the first part in the form of a tongue, sleeve or a pin is guided through an opening of the second part, the first part is brought to abut on the second part and subsequently the end of the connecting element protruding beyond the second part is curled in a deforming process so that the curled end abuts on the second part in a pretensioned manner. A camera module is also described.

In some embodiments, an apparatus comprises a biosensing garment and an electronics assembly. The biosensing garment includes a sensor, a conductive pathway, and a connection region including one or more connectors that are disposed on a PCB. The connection region is electrically coupled to the conductive pathway and the sensor. The connection region is further configured to be electronically coupled to the electronics assembly via at least one conductive contact. In some embodiments, the electronics assembly includes at least one conductive contact that is configured to be electronically coupled to at least one portion of the PCB.

A method for assembling a battery module including a unified connection array with a flexible connector is described. The flexible connector can include a plurality of pads that are secured to a central spine. The flexible connector may be a single piece connector. The flexible connector can include monitors that are mounted to the flexible connector to gather data regarding battery cells of the battery module.

A coupling method of coupling a flexible flat cable to a connector by a robot, includes a preparation step of preparing the connector having an insertion hole into which the flat cable is inserted and a seat having an introduction surface placed at a front side of the insertion hole and continuously coupled to the insertion hole, a first moving step of gripping the flat cable and moving the flat cable to a position facing the seat; and a pressing step of bringing the flat cable into contact with the introduction surface in a posture inclined relative to the seat with an end of the flat cable facing the insertion hole side and pressing the flat cable against the introduction surface, and moving the end toward the connector side.

According to one embodiment, a magnetic disk device includes a housing having a box-shaped base with a bottom wall, a first connection portion provided inside the bottom wall, a second connection portion provided outside the bottom wall and electrically connected to the first connection portion, a control circuit board provided outside the housing, a third connection portion fixed to an inner surface of the control circuit board facing the bottom wall, and abutting on and electrically connecting to the second connection portion, and a reinforcement member positioned between the control circuit board and the bottom wall and provided around the third connection portion.