A connector assembly includes an outer conductive body having a first end configured to mate with a corresponding electrical connector, and a conductive center contact arranged within the outer conductive body. The center contact comprises a first end configured to mate with the corresponding electrical connector and a second end electrically connecting with a first electrical contact of a circuit board. An outer contact is slidably attached to a second end of the outer conductive body and electrically connects with a second electrical contact of the circuit board. An elastic element is provided for biasing the outer contact in a direction away from the outer conductive body and toward the circuit board.

Electrical equipment includes an internal antenna, an external connector, a first radio module, a second radio module, an RF link enabling the second radio module to be connected to the external connector, a detector device arranged, when a test signal is transmitted over the external connector via the RF link, to produce a detection signal representative of whether or not the external antenna is connected to the external connector; and control means arranged to control the second radio module so that it generates and transmits the test signal via the RF link, to acquire the detection signal, and depending on the detection signal, to connect or disconnect the first radio module to or from the external connector.

Electrical equipment includes an internal antenna, an external connector, a first radio module, a second radio module, an RF link enabling the second radio module to be connected to the external connector, a detector device arranged, when a test signal is transmitted over the external connector via the RF link, to produce a detection signal representative of whether or not the external antenna is connected to the external connector; and control means arranged to control the second radio module so that it generates and transmits the test signal via the RF link, to acquire the detection signal, and depending on the detection signal, to connect or disconnect the first radio module to or from the external connector.

A coaxial seizure assembly is disclosed that includes an integrated mechanical stop that prevents over-insertion and maintains a nominal/expected impedance value to enable high-frequency switching, e.g., 1.8-3 Ghz or greater. In more detail, the coaxial seizure assembly includes a coaxial receptacle defined by an opening configured to at least partially receive and couple to a coaxial connector. The opening communicates with a seizure cavity defined within the coaxial seizure assembly. A radio frequency (RF) interconnect at least partially extends into the seizure cavity, with the RF interconnect having a first end to electrically couple to an electrical component and a second end that extends a predetermined angle relative to the first end, e.g., substantially 90 degrees. The second end defines a mating surface that aligns within the seizure cavity such that an imaginary line drawn along an insertion path of a coaxial cable conductor pin intersects with the mating surface.

A coaxial seizure assembly is disclosed that includes an integrated mechanical stop that prevents over-insertion and maintains a nominal/expected impedance value to enable high-frequency switching, e.g., 1.8-3 Ghz or greater. In more detail, the coaxial seizure assembly includes a coaxial receptacle defined by an opening configured to at least partially receive and couple to a coaxial connector. The opening communicates with a seizure cavity defined within the coaxial seizure assembly. A radio frequency (RF) interconnect at least partially extends into the seizure cavity, with the RF interconnect having a first end to electrically couple to an electrical component and a second end that extends a predetermined angle relative to the first end, e.g., substantially 90 degrees. The second end defines a mating surface that aligns within the seizure cavity such that an imaginary line drawn along an insertion path of a coaxial cable conductor pin intersects with the mating surface.

A floating connector includes a shell, a plurality of electrodes, two buckle members and a floating member. The shell has an accommodating space and a plurality of openings. The electrodes are disposed in the accommodating space and penetrate the openings to protrude from the openings. The buckle members are respectively disposed on two sides of the accommodating space. Each of the buckle members includes a fixed part, a contacting part, and an elastic part. The floating member includes a body, a plurality of electrode notches, and a bump. The electrode notches are formed on one side of the body that near the electrodes for receiving the electrodes protruding from the openings. The bump is disposed on the body and correspondingly to the notch, and the width of the bump is not greater than that of the notch, so that the bump is restricted in the notches by the guiding structure.

A floating connector includes a shell, a plurality of electrodes, two buckle members and a floating member. The shell has an accommodating space and a plurality of openings. The electrodes are disposed in the accommodating space and penetrate the openings to protrude from the openings. The buckle members are respectively disposed on two sides of the accommodating space. Each of the buckle members includes a fixed part, a contacting part, and an elastic part. The floating member includes a body, a plurality of electrode notches, and a bump. The electrode notches are formed on one side of the body that near the electrodes for receiving the electrodes protruding from the openings. The bump is disposed on the body and correspondingly to the notch, and the width of the bump is not greater than that of the notch, so that the bump is restricted in the notches by the guiding structure.

A connector that has a conductive shell that supports at least one signal contact therein. The shell comprises a front end for mating with a mating connector and a back end opposite the front end for connecting to a power or data transmission cable. A coupling member is configured to engage the conductive shell and engage a corresponding component associated with the mating connector to mechanically couple the connector and the mating connector together. A plurality of ground connections are provided at the front end of the conductive shell and the front section of the coupling member for grounding.

A coaxial connector system is provided suitable for connection of high-frequency components such as high-band test modules and probes. The coaxial connector system uses a flange mating element aligned using precession guiding pins. A center conductor assembly is captive in a center bore of the flange and includes elastomer contacts which are compressed against the coaxial center conductors of the high=frequency components. The flange mount coaxial connector system provides a robust, mechanically stable mount which minimizes electrical performance changes with mechanical torque as compared to screw on connectors.

Various cellular tower plate connection systems are detailed herein. Such systems can include an antenna plate assembly. This assembly can include an antenna plate and antenna port connectors attached to a first side of the antenna plate. Cable connectors may be present that are attached to a second side of the antenna plate opposite the first side of the antenna plate. The assembly can include a first attachment mechanism that secures antenna port connectors to antenna ports of an antenna system. The antenna port connectors may be arranged on the first side of the antenna plate such that the antenna port connectors mate with the antenna ports of the antenna system in a single possible orientation.