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.

A differential mode instrumentation cable for improving the signal integrity of audio signals in different environments including use of microphones, speaker cable, audiophile cables and analog audio balanced/differential tie lines comprising a first triaxial cable and a second triaxial cable placed side-by-side and mounted together, said first coaxial cable and said second coaxial cable including a wired connection that includes an active driven shield buffer circuit in each triaxial cable having an inner conductor for voltage in from the positive polarity and minus polarity and the voltage out driven guard shield with series breakout resistor connected to the each triaxial inner shield.

A connector assembly includes housing for storing components of the connector assembly. The connector assembly further includes a cable including a cable center conductor, wherein the cable center conductor is configured as a signal conductor. The connector assembly also includes a first dielectric and an alignment dielectric. Each of the first dielectric and the alignment dielectric includes a path to guide the cable center conductor through an angle to a printed circuit board as the cable is axially inserted into the housing.

The present disclosure relates to a coaxial connector assembly comprising a first connector and a second connector adapted to be connected with each other, and a locking mechanism adapted to lock and unlock a connection between the first connector and the second connector. The locking mechanism includes a first locking member having at least one elastic snap-fit element and a second locking member having a locking element adapted to be snap-fitly engaged with the at least one elastic snap-fit element. The first locking member is disposed on an outer periphery of the first connector, and the second locking member is disposed on an outer periphery of the second connector. The elastic snap-fit element is constructed as a cantilever that extends axially toward a direction remote from the second connector, so that it is movable between an unlocking position and a locking position along a radial direction. In the unlocking position, the elastic snap-fit element is pressed down, so that the elastic snap-fit element is disengaged from the locking element, and in the locking position, the elastic snap-fit element springs back to its initial state, so that the elastic snap-fit element is snap-fitly engaged with the lock element.

A coaxial cable includes a coaxial wire in which an inner insulator, an outer conductor and a sheath are sequentially and coaxially provided around a center conductor, and a substrate having a surface on which a first contact pad and a second contact pad are arranged. The sheath is removed at one end portion of the coaxial wire by a predetermined length, so that the inner insulator and the outer conductor are exposed, and a tip end of the inner insulator is removed by a predetermined length, so that the center conductor is exposed. The exposed portion of the center conductor is soldered to the first contact pad with the exposed portion of the inner insulator being bent relative to the sheath, and the exposed portion of the outer conductor is soldered to the second contact pad with being bent in a direction different from the bending direction of the inner insulator. A part of the coaxial wire covered by the sheath is standing at an angle of 30° or greater relative to the surface of the substrate.

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 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 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.

An interposer for a test system includes coaxial cables, each of which is configured to transport a first portion of current originating from a current source, and printed circuit boards (PCBs), each of which is connected to a set of the coaxial cables in order to receive the first portion of the current from each coaxial cable in the set and to transport a second portion of the current. A spring leaf assembly includes spring leaves, each of which is connected to a PCB in order to transport a third portion of the current obtained from the PCB to a device interface board (DIB) that connects to devices under test (DUTs) to be tested by the test system. The coaxial cables on each PCB are arranged in parallel, the PCBs are arranged in parallel, and the spring leaves on each PCB are arranged in parallel.

The present disclosure relates to a coaxial connector assembly comprising a first connector and a second connector adapted to be connected with each other, and a locking mechanism adapted to lock and unlock a connection between the first connector and the second connector. The locking mechanism includes a first locking member having at least one elastic snap-fit element and a second locking member having a locking element adapted to be snap-fitly engaged with the at least one elastic snap-fit element. The first locking member is disposed on an outer periphery of the first connector, and the second locking member is disposed on an outer periphery of the second connector. The elastic snap-fit element is constructed as a cantilever that extends axially toward a direction remote from the second connector, so that it is movable between an unlocking position and a locking position along a radial direction. In the unlocking position, the elastic snap-fit element is pressed down, so that the elastic snap-fit element is disengaged from the locking element, and in the locking position, the elastic snap-fit element springs back to its initial state, so that the elastic snap-fit element is snap-fitly engaged with the lock element.