A stopper (67) of a detector (60) is lockable to a lock surface (17) by entering a lock hole (18) of a lock arm (13) from a deflection space 15. A locking protrusion (45) of a second housing (40) locks to the lock surface (17) by entering the lock hole (18) from a side opposite the deflection space (15). Thus, the housings (10, 40) are held together and the stopper (67) pressed by the locking protrusion (45) separates from the lock surface (17) and the detector can move to the detection position. The locking protrusion (45) has a main body (46) wider than the lock surface (17) of a lock projection (16) and lockable to the lock surface (17). A pressing protrusion (47) narrower than the locking main body 46 projects from the locking main body (46) and enters the lock hole (18) to press the stopper (67).

An electronic charging cable assembly is disclosed. The assembly includes a power connection end adapted to be electrically connected to an electrical power source and a device connection end adapted to be logically connected to an electronic device. The device connection end is electrically connected to the power connection end. A light source is located at the device connection end such that, when the power connection end is electrically connected to the electrical power source and the device connection end is not connected to the electronic device, the light source is illuminated and, when the power connection end is electrically connected to the electrical power source and the device connection end is connected to the electronic device, the light source is not illuminated. An exemplary electrical circuit used to provide this feature and a method of operating the electronic charging cable assembly are also disclosed.

Aspects of the subject disclosure may include, a generator that facilitates generation of an electromagnetic wave, a core, and a waveguide that facilitates guiding the electromagnetic wave towards the core to induce a second electromagnetic wave that propagates along the core. The core and/or the waveguide can be configured to reduce radiation loss of the second electromagnetic wave, propagation loss of the second electromagnetic wave, or a combination thereof. Other embodiments are disclosed.

A clockspring assembly is provided having means to indicate that the clockspring assembly is properly centered upon installation in a motor vehicle. The clockspring assembly includes a hub and a rotor that is rotatable relative to the hub. A ribbon cable is wound about the rotor and provided with one end attached to the rotor and another end attached to the hub. An electronic centering indicator is mounted to the hub and is configured to indicate a centered position of the hub relative to the rotor as a result of a condition occurring when the hub becomes centered with the rotor. Upon the occurrence of the condition, the centering indicator is configured to provide an electronic signal indicating that the clockspring is properly centered.

An electronic device includes an electronic connector, a flexible printed circuit and a structure having a stationary printed circuit board. The electronic connector rotates according to a first pivot axis and a second pivot axis with respect to the structure. The flexible printed circuit is fixed to the electronic connector and the stationary printed circuit board, and transfers an electronic current between the electronic connector and the stationary printed circuit board. The flexible printed circuit board comprises a first partly circular bend moving in response to the rotation of the electronic connector according to the first pivot axis and a second partly circular bend moving in response to the rotation of the electronic connector according to the second pivot axis.

It is aimed to provide a connector capable of ensuring the integrity of a lock arm and a detector in the process of deflecting the lock arm and enhancing a degree of freedom in designing the lock arm. A detector (60) movable in a front-back direction between a standby position and a detection position is assembled with a housing (10). The detector (60) includes a contact portion (78) displaceable together with a front end part (27) of a lock arm (23) during the interference of the front end part (27) of the lock arm (23) and a mating lock (44) contacting the front part (27) of the lock arm (23) in a height direction intersecting with the front-back direction at the standby position. The contact portion (78) stands up in the height direction from a front end part of the locking arm and then projects forward.

An electronic unit has an electronic assembly that comprises a circuit board, and also having a conductor that is connected to said electronic assembly and is provided with a flat connection end. At least one piercing contact protrudes down from the circuit board and connects the conductor electrically to the electronic assembly. The piercing contact penetrates the connection end of the conductor while forming an electrical connection with a conductor track of the conductor. The electronic component is particularly suited as a capacitive proximity sensor for a vehicle.

Methods for collecting information regarding a remote connector port that is connected to a patch panel connector port by a communications cable that has at least one data communications channel and a separate control channel are provided in which a first conductor of the separate control channel of the communications cable is biased to power an integrated circuit chip that is associated with the remote connector port. A first signal is transmitted over the separate control channel of the communications cable to the integrated circuit chip associated with the remote connector port. A second signal is received from the integrated circuit chip over the separate control channel of the communications cable in response to the first signal. The second signal includes information regarding the remote connector port.