The present disclosure relates to an LED LAN cable connector capable of high speed data transmission, and according to the present disclosure, it is possible to effectively prevent the data speed from decreasing and the data from being blocked when applying external power source to the LAN cable connector where an LED is installed.

A first connector pin to a third connector pin have a substantially L-shaped cross-sectional shape formed by a horizontal part embedded in the top of an inner housing part by resin molding and a vertical part continuous with and protruding upwardly orthogonal to the horizontal part. A fourth connector pin has a substantially I-shaped cross-sectional shape having only the vertical part. The horizontal part of the first connector pin is provided so as to surround the first end of the first connector pin, the horizontal part and the first end of the second connector pin, the horizontal part and the first end of the third connector pin, and is integrated and connected to the fourth connector pin. A chip capacitor is attached to the connector pins by a joining member. Thus, the connector pins are connected to each other via the chip capacitors.

The present disclosure relates to an LED LAN cable connector capable of high speed data transmission, and according to the present disclosure, it is possible to effectively prevent the data speed from decreasing and the data from being blocked when applying external power source to the LAN cable connector where an LED is installed.

A rail vehicle control relay board includes a main frame, a mother board and a daughter board assembly which are arranged in the main frame, the main frame includes a board face mounting frame and a daughter board mounting frame which protrudes from the board face mounting frame, the mother board is arranged in the board face mounting frame, and multiple daughter board assemblies perpendicular to the mother board are arranged side by side in the daughter board mounting frame, the daughter board assemblies are electrically connected to the mother board, and multiple first connectors configured to perform output outwards are arranged on the mother board. The rail vehicle control relay board has a high strength, and may reduce the daughter board loosening faults, extend a wiring space and increase the number of relays arranged.

An adapter has two conductors each with a U-shaped bend forming upper longer legs and lower shorter legs. The conductors face each other with the longer legs linearly aligned with each other and the shorter legs aligned with each other, thereby forming a first gap between the longer legs and a second gap between the shorter legs. The first gap is substantially smaller than the second gap, so that an electrical package can be placed across the first gap to contact the two upper longer legs, while the two shorter legs are spaced further apart to span a larger gap between conductors of a connector. Thus, the adapter enables the electrical package to be connected to conductors having a gap that is larger than the electrical package.

A cable card assembly for an electrical connector includes a circuit card having circuit conductors defining signal transmission paths through the circuit card. The circuit conductors include cable pads at the cable end and capacitor pads adjacent the corresponding cable pads. The cable card assembly includes twin axial cables electrically coupled to the circuit card. Each twin axial cable includes a pair of signal conductors and a cable shield surrounding the pair of signal conductors to provide electrical shielding for the corresponding signal conductors. The signal conductors configured to be electrically connected to the circuit conductors of the circuit card. The twin axial cable extending along a cable axis. The cable card assembly includes capacitors coupled to the circuit card. Each capacitor is connected between the corresponding cable pad and the corresponding capacitor pad. The capacitor is oriented perpendicular to the corresponding cable axis.

There is provided a connector connectable to a mating connector that includes a first jack terminal configured to be coupled to a first plug terminal of the mating connector; a second jack terminal configured to be coupled to a second plug terminal of the mating connector; and a third jack terminal configured to be coupled to the second plug terminal of the mating connector, and having a resistor and a capacitor connected in series thereto. Upon the connector being separated from the mating connector, the second jack terminal is separated from the second plug terminal after the third jack terminal is separated from the second plug terminal, and the first jack terminal is separated from the first plug terminal after the second jack terminal is separated from the second plug terminal.

A transmission cable structure with capacitor device includes two connectors and positive and negative electrode conductive wires connected to the connectors and a capacitor device securely disposed between the connectors. The capacitor device has a first electrode connected to the positive electrode conductive wire and a second electrode connected to the negative electrode conductive wire. When the connectors are respectively connected with a first and a second electrical apparatuses, the capacitor device and the second electrical apparatus form a parallel circuit. When the first electrical apparatus supplies power for the second electrical apparatus, the capacitor device is charged by the first electrical apparatus to charge the second electrical apparatus, whereby the instantaneous surges are absorbed to protect the second electrical apparatus from the instantaneous surges. Also, a filtering function is provided. The capacitor device also can enhance the data transmission speed.

The invention relates to a camera (2) for a motor vehicle (1), which includes a printed circuit board (16), on which a current connector (29) and a communication bus connector (30) and a video interface connector (31) each for connecting to the motor vehicle (1) are disposed, wherein the video interface connector (31) is connected to a capacitor (25) and a parallel-to-serial converter (26), wherein the video interface connector (31) and/or the capacitor (25) and/or the parallel-to-serial converter (26) are surrounded by a device (32) shielding electromagnetic radiation.

A circuit board for a high speed communication jack including a rigid circuit board in the housing having a substrate, a plurality of vias extending through the substrate with each via being configured to accommodate a pin on the housing, a plurality of traces on a middle layer in the substrate, with each trace extending from a corresponding one of the plurality of vias, a first shielding layer on a first side of the middle layer in the substrate, a second shielding layer on a second side of the middle layer in the substrate, and a third shielding layer adjacent to the second shielding layer.