A connection pin for an expansion socket can be treated to improve signal (e.g., reduce noise) for high speed applications. A connection pin can be treated to have a conductive plating covering a proximal region of the connection pin. Electrical signals between an expansion card in contact with the connection pin and the circuit board to which the connection pin is coupled can pass directly through the conductive plating of the proximal region. However, the distal region of the connection pin can be treated to be devoid of the conductive plating, such as by being covered with a high dielectric loss and/or high-resistance material or through removal of the conductive plating in that region. Thus, electrical signals passing through the connection pin will tend to pass through the conductive plating rather than along the distal region of the pin. Thus, signal reflections and other artifacts and noise can be avoided.

A connection pin for an expansion socket can be treated to improve signal (e.g., reduce noise) for high speed applications. A connection pin can be treated to have a conductive plating covering a proximal region of the connection pin. Electrical signals between an expansion card in contact with the connection pin and the circuit board to which the connection pin is coupled can pass directly through the conductive plating of the proximal region. However, the distal region of the connection pin can be treated to be devoid of the conductive plating, such as by being covered with a high dielectric loss and/or high-resistance material or through removal of the conductive plating in that region. Thus, electrical signals passing through the connection pin will tend to pass through the conductive plating rather than along the distal region of the pin. Thus, signal reflections and other artifacts and noise can be avoided.

One example includes a signal connector system. The system includes a first connector comprising a first housing and first contacts formed from a self-passivating transition metal and configured to conduct an AC signal. The system also includes a second connector comprising a second housing and second contacts formed from the self-passivating transition metal and configured to electrically couple to a respective one of the first contacts to conduct the AC signal. The first and second housings can be coupled to enclose the signal connector and to create at least one fluid-filled channel between each of the electrically-connected first and second contact pairs in response to fastening the first and second connectors while submerged in a respective fluid to provide a resistive path in the at least one fluid-filled channel for providing signal isolation between each of the electrically-connected first and second contact pairs.

A male F-type coaxial cable connector including a nut, a body, a post, and a spacer, the spacer for bearing on the nut.

A high-bandwidth underwater electrical connector is provided that includes first and second connectors each having free space optical transceivers. The electrical connector further includes self-passivating transition metal contacts that form a non-conductive outer layer when immersed in a fluid. The first and second free space optical transceivers transmit and receive data at high data speeds.

Contacts that can be highly corrosion resistant, can be readily manufactured, and can conserve precious materials. One example can provide contacts having a layer of a precious-metal alloy to improve corrosion resistance. The precious-metal-alloy layer can be plated with a hard, durable, wear and corrosion resistant plating stack for further corrosion resistance and wear improvement. The resources consumed by a contact can be reduced by forming a bulk or substrate region of the contact using a more readily available material, such as copper or a material that is primarily copper based.

An electrical connector includes a substrate and multiple terminals. The substrate is provided with multiple accommodating holes running through the substrate vertically. A shielding member is provided on a lower surface of the substrate. The terminals are correspondingly accommodated in the accommodating holes respectively. The terminals include multiple signal terminals and at least one ground terminal. An interval exists between the ground terminal and the shielding member. The ground terminal has a conducting portion extending downward out of a corresponding accommodating hole. The conducting portion is soldered to a main circuit board through a solder, and the solder is in contact with the conducting portion and the shielding member. According to the present invention, the conducting portion of the ground terminal is connected with the shielding member through the solder, thereby reducing a spurious charge, reducing the capacitance, and improving a high frequency.

A cable system component includes a nut having a seal-grasping surface portion and a seal having an elastically deformable tubular body attached to the nut. The body has a posterior sealing surface that cooperatively engages the seal-grasping surface portion of the nut and a forward sealing surface configured to cooperatively engage an interface port. The seal includes a nonconductive elastomer overlying a conductive elastomer in a radial dimension of the seal. The conductive elastomer is configured to make an electrical ground connection with the interface port before a center conductor of the coaxial cable makes an electrical connection with an internal contact of the interface port when the nut is coupled with the interface port.

A connector includes a base, a transmission interface, a shielding cover and a shielding layer. The base includes a slot. The transmission interface includes a clamping portion and a plugboard. The clamping portion is clamped in the slot and a portion of the plugboard protrudes out of the base. The shielding cover has an accommodation space and a shielding layer. The accommodation space is disposed to accommodate the base and the transmission interface, and the shielding layer is electroplated on an inner side surface of the shielding cover. The shielding cover covers the base and the transmission interface and is disposed to block electromagnetic waves generated by the transmission interface.

The present invention relates to a method for producing at least one high-frequency contact element or a high-frequency contact element arrangement comprising at least one such high-frequency contact element. The method includes producing a basic body part of each high-frequency contact element from a dielectric material by means of an additive manufacturing method, wherein the basic body part has a bushing between a first end and a second end of a longitudinal extent of the basic body part. In addition, the method includes coating the dielectric basic body part with an electrically conductive layer and removing the electrically conductive layer in a region surrounding the bushing at the first end and at the second end of the basic body part so as to form an electrically conductive coating on the outer conductor side and an electrically conductive coating on the inner conductor side. The present invention also relates to a high-frequency contact element or a high-frequency contact element arrangement.