Apparatus (2) is described including one or more signal sources (6). The apparatus (2) also includes a measurement front end (7) having at least first (+V.sub.in)) and second (−V.sub.in) inputs. The apparatus (2) also includes a substantially planar connector (1) having a length (L) between first (1a) and second (1b) ends and supporting a number of conductors (3) spanning between the first (1a) and second (1b) ends. At each point between the first (1a) and second (1b) ends the conductors (3) are substantially equi-spaced from one another within the substantially planar connector (1). The conductors (3) include at least one signal conductor (8) connecting the signal sources (6) to the first input (+V.sub.in). The conductors (3) also include at least two further conductors (10, 11) connecting to the one or more signal sources (6). One or both of the two further conductors (10, 11) also connect to the second input (−V.sub.in). Each of the at least one signal conductor (8) and the at least two further conductors (10, 11) belongs to one or more closed loops. The one or more closed loops have areas and impedances configured such that in response to a uniform time-varying external magnetic field being applied to the apparatus, a first unwanted electromotive force induced at the first input (+V.sub.in) will be substantially equal to a second unwanted electromotive force induced at the second input (−V.sub.in).

Apparatus (2) is described including one or more signal sources (6). The apparatus (2) also includes a measurement front end (7) having at least first (+V.sub.in)) and second (−V.sub.in) inputs. The apparatus (2) also includes a substantially planar connector (1) having a length (L) between first (1a) and second (1b) ends and supporting a number of conductors (3) spanning between the first (1a) and second (1b) ends. At each point between the first (1a) and second (1b) ends the conductors (3) are substantially equi-spaced from one another within the substantially planar connector (1). The conductors (3) include at least one signal conductor (8) connecting the signal sources (6) to the first input (+V.sub.in). The conductors (3) also include at least two further conductors (10, 11) connecting to the one or more signal sources (6). One or both of the two further conductors (10, 11) also connect to the second input (−V.sub.in). Each of the at least one signal conductor (8) and the at least two further conductors (10, 11) belongs to one or more closed loops. The one or more closed loops have areas and impedances configured such that in response to a uniform time-varying external magnetic field being applied to the apparatus, a first unwanted electromotive force induced at the first input (+V.sub.in) will be substantially equal to a second unwanted electromotive force induced at the second input (−V.sub.in).

An electrical connector includes an insulative housing, a number of terminals and a metallic shielding plate s retained in the insulative housing, and a shielding shell attached to the insulative housing. The insulative housing has a base portion and a tongue portion extending forwardly from the base portion along an insertion direction. The terminals define a number of first contacts and second contacts. The first contacts and second contacts respectively define a pair of grounding contacts located at two sides thereof. Each grounding contact of the second contacts has a hook portion bent upwardly and extending inwardly from outmost edge thereof and located above the grounding contact of the first contacts located at the same side. A free end of the hook portion is contacted with the grounding contact of the first contacts at same side physically and electrically.

A retention apparatus for a shielded cable is described. In one embodiment, the apparatus comprises a substrate having a ground; a connector coupled to the substrate; a cable shielded with a conductive material and having an end connectable to the connector to electrically connect with the connector; an electrically conductive material coupled to the ground of the substrate; and a grounding retention mechanism to cause the electrically conductive material to electrically connect the cable to the ground of the substrate by applying a force to the cable shield.

A multipolarized signal terminal connector for an accessory, which is applied to an accessory shoe device having a defined shape. The signal terminal connector includes a first surface opposed to an attaching direction of an accessory, a first terminal row provided the first surface, a second surface which is inclined with respect to the first surface by a predetermined angle, and a second terminal row provided in the second surface. The second surface is inclined with respect to the first surface, in a predetermined direction orthogonal to the attaching direction of the accessory and a direction in which the terminals of the second terminal row are arranged, and is displaced with respect to the first surface in the predetermined direction.

An apparatus and method for crosstalk compensation in a jack of a modular communications connector includes a flexible printed circuit board connected to jack contacts and to connections to a network cable. The flexible printed circuit board includes conductive traces arranged as one or more couplings to provide crosstalk compensation.

Electromagnetic shielding about a part connected with a wiring substrate is easily and reliably carried out by a simple configuration without impairing productivity. A fixed shield plate provided at a shield shell member of an electric connector mounted on a wiring substrate is disposed to be opposed to a vicinity of a substrate connecting leg portion of a contact member. A movable shield plate covering a shell opening by a moving operation is provided. At least the substrate connecting leg portion of the contact member is covered from an outer side by fixed and movable shield plates, thereby well carrying out electromagnetic shielding (shielding) with respect to the part connected with the wiring substrate. Until the movable shield plate is subjected to the moving operation, the part connected with the wiring substrate can be checked well through the shell opening.

A radio-frequency connector assembly includes a radio-frequency line, connector male terminals, connector female terminals, and a circuit board, wherein each connector male terminal includes a male terminal substrate; each connector female terminal includes a female terminal substrate; the connector male terminal further includes a shielding case which shields the male terminal substrate and is conductive with the radio-frequency line in a grounding manner; and the connector female terminal further includes a shielding frame which is internally provided with the female terminal substrate and is circumferentially seamless entirely, and the bottom end of the shielding frame makes contact with the circuit board to form an annular contact region, so that signals of the connector female terminals will not leak sideways; and the shielding cases can prevent signal leakage and signal interference from the top of the shielding frame, so that matched signal terminals are kept in a fully-shielded operating environment.

An electrical connector includes multiple terminals fixed to an insulating body. Each terminal has a contact portion electrically connected with a mating connector, and a conducting portion located behind the contact portion. The conducting portion extends out of the insulating body and is electrically connected with a circuit board. A grounding shell wraps outside the insulating body. A shielding shell rotates relative to the insulating body between a closed position and an open position. A first end of the shielding shell is electrically connected with the grounding shell. When the shielding shell is at the closed position, a second end of the shielding shell is electrically connected with at least one grounding medium electrically connected with the circuit board. When the shielding shell is at the open position, an observation window is formed between the shielding shell and the grounding medium to expose the conducting portions of the terminals.

An electronic device according to various embodiments of the disclosure may include: a housing which includes a first plate facing a first direction, a second plate facing a second direction opposite to the first direction, and a lateral member covering at least part of the space between the first and second plates; a display disposed to be visible in at least part of the first plate; a first circuit board which includes a first face facing the first direction and a second face facing the second direction, and which is disposed in the second direction of the display; a second circuit board which is disposed not to overlap at least in part with the first printed circuit board, and which is electrically coupled with the first circuit board; a socket mounted to the second circuit board; at least one or more metal structures disposed on the first circuit board to transfer, to another component, heat of at least one or more exothermic elements mounted on the first circuit board; and a ground path constructed in at least part of the second circuit board so as to be electrically coupled to the first circuit board or the metal member or the first circuit board and the metal structure.