A method and apparatus is presented for strain relief for mil-spec RF cabling connectors. When the RF signals are carried on the cables, they are either attached to connectors to increase their lengths or they get attached to hardware assembly that receives and transmits RF signals. At connections, strain relief is provided so that any movement of the cables does not convey stress and strain to the points where cable joins the connector or its mate. A concise, space restricted strain relief solution is provided by use of clamp, cover or shrink tubing to transfer cables in all four directions. The concentric cables line up in small dimensions and are replaceable individually as opposed to discard of entire mesh of cables on single cable failure.

A connector is provided and includes an alignment plate defining major and minor apertures, a capture plate and a pin plate. The capture plate includes an outer body defining an opening, an inner body traversing the opening and first elastic elements extending from the inner body to generate first biases. The capture plate is securable to the alignment plate to position the inner body between the major apertures. The pin plate defines intermediate apertures and includes pins and second elastic elements to generate second biases opposing the first biases. The pin plate is interposable between the alignment and capture plates whereby the intermediate and major apertures align and the pins extend through the minor apertures.

A coaxial connector assembly includes: a first plurality of first coaxial connectors mounted within a shell, the shell defining a plurality of electrically isolated cavities, each of the first coaxial connectors being located in a respective cavity; a plurality of first coaxial cables, each of the coaxial cables attached to a respective one of the first coaxial connectors; a second coaxial connector mounted within the shell, the second coaxial connector being smaller that the first coaxial connectors; and a second coaxial cable attached to the second coaxial connector, the second coaxial cable being smaller than the first coaxial cables.

An interface connector, comprising a housing, a first heat dissipating member, and a second heat dissipating member. A first accommodating space and a second accommodating space are disposed in the housing. The first accommodating space is adjacent to the second accommodating space. The first accommodating space accommodates a first mating connector. The second accommodating space accommodates a second mating connector. The first heat dissipating member is disposed at the outside of the housing and passes through the housing. The first heat dissipating member extends into the first accommodating space to be connected to the first mating connector. The second heat dissipating member is disposed in the housing. The second heat dissipating member extends into the second accommodating space to be connected to the second mating connector.

A ganged connector assembly includes: first, second, third and fourth coaxial cables; first, second, third and fourth coaxial connectors, each of the coaxial connectors connected with a corresponding one of the coaxial cables; a shell surrounding the coaxial connectors, the shell configured to electrically isolate each of the coaxial connectors from the other coaxial connectors, wherein the coaxial connectors are arranged in a generally square pattern; and a strain relief boot comprising: first and second cover pieces that are assembled to create a cover around portions of the coaxial cables and the coaxial connectors; and first and second braces that reside within the cover, the first brace being positioned between first and second of the coaxial connectors, and the second brace being positioned between third and fourth of the coaxial connectors.

A connector is provided and includes an alignment plate defining major and minor apertures, a capture plate and a pin plate. The capture plate includes an outer body defining an opening, an inner body traversing the opening and first elastic elements extending from the inner body to generate first biases. The capture plate is securable to the alignment plate to position the inner body between the major apertures. The pin plate defines intermediate apertures and includes pins and second elastic elements to generate second biases opposing the first biases. The pin plate is interposable between the alignment and capture plates whereby the intermediate and major apertures align and the pins extend through the minor apertures.

An antenna feeding network for a multi-radiator antenna, the antenna feeding network comprising at least two coaxial lines. Each coaxial line comprises a central inner conductor and an elongated outer conductor surrounding the central inner conductor. At least a first inner conductor and a second inner conductor of the at least two coaxial lines are indirectly interconnected.

The present invention proposes a method for providing a broadcast content in an apparatus, the method comprising: requesting a filter code to an application running on the apparatus by using a first Application Programming Interface (API); receiving a JavaScript Object Notation (JSON) object from the application in response to the first API; storing the filter code; receiving an Extended File Delivery Table (EFDT) having a first filter code associated with a first file; and selectively downloading the first file by comparing the stored filter code with the first filter code in the EFDT.

An adaptive connector comprising a contact jack and a lamella comb, wherein the lamellae of the lamella comb electrically contact the contact jack, characterised in that the contact jack is connected in a mechanically inseparable but movable manner with the lamella comb. The contact jack can be pivoted relatively to the lamella comb with an angular range of more than 2 degrees while maintaining contact between the contact jack and the lamellae of the lamella comb, and/or the contact jack can be moved translationally relatively to the lamella comb in at least one direction within a translational range of more than 1 millimetre. Moreover, an adaptive connector comprising two or more adapter elements that are electrically separate from each other. Each adapter element comprises a connection jack or a connection lamella device at each of two ends of the adapter element, the connection jack or connection lamella device of one end being electrically connected to the connection jack or connection lamella device of the other end. The adapter elements are connected with each other in a mechanically inseparable but movable manner. Any of the adapter elements can be pivoted relatively to at least one other of the adapter elements with an angular range of more than 4 degrees and/or any of the adapter elements can be moved translationally relatively to any other of the adapter elements in at least one direction by more than 2 millimetre. Finally, a system comprising the adaptive connector and a counter connector.

A communication cable includes a first leaky coaxial cable, a first leaky coaxial cable, and an approach cable. The first leaky coaxial cable has a first end and a second end connected to a communication device. The second leaky coaxial cable has a third end and a fourth end different from the first end and second end of the first leaky coaxial cable. The approach cable has a fifth end connected to the communication device and a sixth end connected to the third end of the second leaky coaxial cable, wherein the sixth end is positioned near the second end of the first leaky coaxial cable.