Portable electronic devices by their nature are designed to be regularly physically repositioned and relocated, which can cause significant mechanical stresses on internal components, including printed circuit boards (PCBs). This is particularly true when a portable electronic device is handled roughly. These significant mechanical stresses can cause threaded mechanical fasteners securing the PCBs to become dislodged. A dislodged threaded mechanical fastener may contact electrically conductive features of the PCB or other internal components, thereby causing a ground fault or short. At a minimum, this may cause the portable electronic device to not work well, or at all. Further, this may cause the portable electronic device to overheat and become a fire hazard. The presently disclosed technology detects if the threaded mechanical fasteners within a portable electronic device become dislodged. A user of the portable electronic device may then be warned, and the portable electronic device may be powered down.

A connection element for electrically connecting a circuit carrier to another circuit carrier includes at least one solder connection for soldering onto the surface of the circuit carrier and a connection pin, which is electrically connected to the solder connection, for inserting into the other circuit carrier. The connection element has a holding body and a contact element which is connected to the holding body and which is designed to be elastic. The contact element has an end section, the solder connection being formed on the end section. The connection element has a locking element which is connected to the connection element in a movable manner back and forth between a locking position and a release position. The locking element is designed to limit the displacement of the contact element in the locking position and release an elastic movement of the contact element in the release position.

One aspect provides an apparatus for locking circuit boards in position between a pair of guide rails. The apparatus can include a slider attached to a sidewall of one guide rail. The slider is allowed to slide along the guide rail within a predetermined range and one or more plunger-and-spring assemblies. A respective plunger-and-spring assembly comprises a plunger and a spring surrounding the plunger, and the plunger is inserted into a through-hole on the sidewall of the guide rail such that a first end of the plunger can be aligned with a notch on a corresponding circuit board and a second end of the plunger is in contact with the slider. Sliding of the slider causes the spring to compress and decompress and the first end of the plunger to move in and out of the notch on the circuit board, thereby facilitating locking and unlocking of the circuit board.

A grid array capacitor can be used to physically and electrically couple an integrated circuit (IC) package to a printed circuit board (PCB). The grid array capacitor includes an inner conductor and an inner dielectric coaxially surrounding the inner conductor. A secondary conductor can be located to surround, in a coaxial orientation, the inner dielectric. Both the inner conductor and the secondary conductor can be electrically connected to the IC package and to the PCB. In certain applications, the structure of the inner conductor, inner dielectric, and secondary conductor can provide capacitance used to decouple electronic circuits.

An electronic device includes: a circuit board having a wiring board on which wiring is formed, and an electronic component that is electrically and mechanically connected to the wiring via a first solder. A base is provided to accommodate the circuit board, and has a side wall that faces a side surface of the wiring board. A leaf spring arranged on the circuit board, and is configured to be contactable with the base. The leaf spring includes a fixing portion arranged on the circuit board and a pressing portion extending from and connected to the fixing portion and pressing the side wall, and the pressing portion in a biased state toward a housing establishes a contact thereto when the circuit board is put in and accommodated by the base.

An implantable connector for connecting an electronics package and a neural interface is made by way of a compressible contacts (e.g., a spring) that physical contacts a corresponding exposed bond pad. The compressible contact is held in compression with the exposed bond pad using a mechanical coupler. The compressible contact is physically separated and electrically isolated from other contacts by way of a compressible gasket. The compressible gasket is also held in compression using the mechanical coupler.

A touch LED component and a touch device, and the touch LED component includes a metal cap, a touch button sheathed on an inner wall of the metal cap, and an LED lamp bead coupled to an inner wall of the touch button, a first through hole formed at the top of the metal cap, an induction pin installed at the bottom of the touch button, and an anode pin and a cathode pin installed on both sides of the bottom of the LED lamp bead respectively. The touch device includes a touch panel, a circuit board, and plural touch LED components. The touch LED component with high integration can be packaged by carrier tapes to facilitate automatic plug-ins and simplify production and assembling processes for mass production. The touch device has the features of simple structure, high reliability, good effect and long life.

An implantable electronic device includes a flexible circuit board, one or more circuit components attached to the flexible circuit board and configured to convert electrical energy into electrical pulses, and one or more electrodes attached to the flexible circuit board without cables connecting the electrodes to each other or to the flexible circuit board, the one or more electrodes configured to apply the electrical pulses to a tissue adjacent the implantable electronic device.

A stretchable interconnect structure for electrically connecting electronic devices and a method of fabricating a stretchable interconnect structure for electrically connecting electronic devices. The method comprises the steps of providing an electrically conductive wire having a 3-dimensional helical form; and embedding the electrically conductive wire in a substrate made from an elastic material.

One aspect provides an apparatus for locking circuit boards in position between a pair of guide rails. The apparatus can include a slider attached to a sidewall of one guide rail. The slider is allowed to slide along the guide rail within a predetermined range and one or more plunger-and-spring assemblies. A respective plunger-and-spring assembly comprises a plunger and a spring surrounding the plunger, and the plunger is inserted into a through-hole on the sidewall of the guide rail such that a first end of the plunger can be aligned with a notch on a corresponding circuit board and a second end of the plunger is in contact with the slider. Sliding of the slider causes the spring to compress and decompress and the first end of the plunger to move in and out of the notch on the circuit board, thereby facilitating locking and unlocking of the circuit board.