A modularly expandable electronic control unit comprises: an electronic circuit board on which a conductor track is disposed on a side in a region of lateral edges and enclosing an inner region and separating it from an outer region of the side, a housing having two halves for receiving the electronic circuit board. With the housing assembled, at least one housing half has an encircling electrically conductive shielding wall which rests on and establishes electrical contact with the conductor track and/or has at least one receptacle accessible from outside the assembled housing. The receptacle is disposed so the electronic module placed in the receptacle may be electrically connected to a module connection port disposed in the outer region of the electronic circuit board. The electronic circuit board has electrical connections between the module connection port and one or more electronic assemblies disposed on the inner region.

An electronic device includes a first housing having a first through-hole, of which a first opening and a second opening are communicated with each other, and a second housing connected to the first housing to be rotatable. A flexible printed circuit board (FPCB) extends from the first housing to the second housing via the first through-hole. The FPCB includes a plurality of layers, a first sealing member disposed in the first through-hole and surrounding the FPCB, and a lamination part toward the first sealing member. A portion of a first layer and/or a second layer corresponding to the second lamination part includes at least one first valley extending from a surface that faces an adjacent layer in a lengthwise direction of the FPCB. The lamination part includes a first adhesive layer interposed between the first layer and the second layer and filling the at least one first valley.

A surgical instrument connectable to a surgical energy module that is configured to provide a first drive signal at a first frequency range for driving a first energy modality and a second drive signal at a second frequency range for driving a second energy modality is provided. The surgical instrument can comprise a surgical instrument component configured to receive power from a direct current (DC) power source, an end effector, and a circuit. The circuit can be configured to convert the first electrical signal to a DC voltage, apply the DC voltage to the surgical instrument component, and deliver the second energy modality to the end effector according to the second drive signal. Alternatively, the circuit can be disposed within a cable assembly configured to connect the surgical instrument to the surgical energy module.

A system includes a housing of a printed circuit board arranged in the housing and at least one functional element, wherein the housing has at least one exchangeable side surface, wherein openings which correlate to electrical connections of the printed circuit board are provided in the at least one exchangeable side surface, and wherein the functional elements each pass through an opening in the side surface to the electrical connections of the printed circuit board assigned to them and are connected to said connections.

A device is provided with an electronics housing for accommodating electronics for a sensor or an actuator, and a functional housing separate from the electronics housing in a disassembled state of the device. The functional housing accommodates the sensor or the actuator. The two housings are connected to each other in an assembled state of the device. During the transfer of the device into its assembled state, the housings can be connected in a form-locked manner to each other only by a linear movement thereof relative to each other along an assembly axis. The two housings include latch mechanisms corresponding to each other for this purpose.

A housing for a consolidated electronics unit of a vehicle includes side walls mountable to vehicle rails of the vehicle, a bottom wall coupled to the side walls, and a cover removably coupleable to the side walls and configured to form a portion of an interior surface of a vehicle cabin of the vehicle. The cover, the side walls, and the bottom wall form a cavity configured to enclose control units that are in electronic communication with feature units disposed throughout the vehicle.

A self-aligning mechanical mount and electrical connection system for an electronic module comprises a mechanical mount assembly configured to be integrated into or attached to a base frame and defining a mount connection position assurance (CPA) feature for self-aligning and securing of the electronic module therein, and an electrical connection assembly configured to be integrated into or attached to the mechanical mount assembly and comprising a modular electrical connector (i) being electrically connected to an electrical backbone wire cable and (ii) defining a connector CPA feature for self-aligning the modular electrical connector with a corresponding electrical connector integrated into or attached to the electronic module when the electronic module is secured in the mechanical mount assembly.

A component carrier includes a stack having at least one electrically conductive layer structure and/or at least one electrically insulating layer structure and a magnetic element assembled to the stack. The magnetic element includes a magnetic matrix and an inductive element. The inductive element is at least partially enclosed by the magnetic matrix, so that an electric current flow direction through the inductive element is essentially in a horizontal direction with respect to the stack. Further, a magnetic inlay and a manufacturing method are described.

An electronic device with storage functionality is provided. The electronic device includes a first housing member, a first circuit board, a second housing member and a second circuit board. The first circuit board is connected to the first housing member. The second circuit board is coupled to the first circuit board and is parallel to the first circuit board. The first housing member includes two hooks, and the hooks are wedged against the first edge of the second circuit board.

A gate driver includes: driver boards mountable on an IGBT module which is a driving-target external device; gate driver circuits which are formed on the driver boards and each apply a drive signal generated using power and a signal which are externally input through an input connector, to semiconductor elements of the IGBT module; and an insulating surrounding member disposed to surround a peripheral edge of the input-side driver board.