A coaxial connector for interconnection with a coaxial cable with a solid outer conductor by ultrasonic welding is provided with a monolithic connector body with a bore. An annular flare seat is angled radially outward from the bore toward a connector end of the connector, the annular flare seat open to the connector end of the connector. An inner conductor cap is provided for interconnection with an inner conductor of the coaxial cable by ultrasonic welding. The ultrasonic welding of each of the inner and outer conductor interconnections may be performed via inner conductor and outer conductor sonotrodes which are coaxial with one another, without requiring the cable and or connector to be removed from their fixture.

A coaxial connector in combination with a coaxial cable is provided with an inner conductor supported coaxial within an outer conductor, a polymer jacket surrounding the outer conductor. A unitary connector body with a bore is provided with an overbody surrounding an outer diameter of the connector body. The outer conductor is inserted within the bore. A molecular bond is formed between the outer conductor and the connector body and between the jacket and the overbody. An inner conductor end cap may also be provided coupled to the end of the inner conductor via a molecular bond.

Provided are coaxial waveguide microstructures. The microstructures include a substrate and a coaxial waveguide disposed above the substrate. The coaxial waveguide includes: a center conductor; an outer conductor including one or more walls, spaced apart from and disposed around the center conductor; one or more dielectric support members for supporting the center conductor in contact with the center conductor and enclosed within the outer conductor; and a core volume between the center conductor and the outer conductor, wherein the core volume is under vacuum or in a gas state. Also provided are methods of forming coaxial waveguide microstructures by a sequential build process and hermetic packages which include a coaxial waveguide microstructure.

The invention relates to a method for producing a stranded inner conductor (1), and to a coaxial cable (9). In a first step, a stranded inner conductor (2) is provided, which consists of several wires (3) twisted together. Then the stranded inner conductor (1) is rotary swaged by means of a rotary swaging device (10). In a further step, the rotary swaged stranded inner conductor (3) is enclosed with a dielectric (4). In a further step, the dielectric (4) is enclosed with an outer conductor (5) and a cable sheath (6).

A package structure comprises: a plurality of metal parts, wherein each metal part is made of metal and each two adjacent metal parts are spaced apart by a gap being filled with an insulating material; a first insulating layer, disposed over a top of the plurality of metal parts and the top surface of a conductive element; and a first conductive layer, disposed over the first insulating layer, wherein a first conductive pattern electrically connects a first terminal of the conductive element to a first metal part through at least one first via disposed in the first insulating layer, wherein a bump is disposed in the first insulating layer and electrically connected to a second terminal of the conductive element.

An apparatus for processing a cable including an insulating member, a shielding layer, and a conductor, the apparatus includes a frame forming a housing having an aperture configured to receive an end portion of the cable; a first gripping member disposed within the housing and being configured to grip the cable; and a second gripping member disposed within the housing and being configured to grip the cable; wherein the second gripping member is mounted within the housing so as to be movable relative to the first gripping member to effect fanning and cutting of a portion of the shielding layer,

The preservation of the user interface state of first application on a first device allows, in one embodiment, a user to resume use of at least a portion of the user interface state on a second application on second devices. The first and second applications can be the same or different (with some common user interface UI features or elements and other UI features that are different). Other embodiments are also described.

A terminal treatment apparatus for a coaxial cable including a core member having an inner conductor covered with an insulator, an outer conductor provided around the core member and formed of a plurality of wires, and a sheath covering an outer circumference of the outer conductor, includes a widening terminal to widen the outer conductor away from the core member by compressing a terminal-near portion of the exposed outer conductor from an outer circumferential side of the coaxial cable to deform the terminal-near portion of the exposed outer conductor.

A crimp tool for creating a crimp connection between a coaxial cable having an inner conductor, an outer conductor, and a coaxial connector having an outer conductor part, employing an anvil to hold the outer conductor part, the anvil having a recess with an arcuate face of a first radius of curvature, and anvil arm points at each end of the arcuate face, and employing a die to apply the crimping force, the die having a recess with an arcuate face of a second radius of curvature, wherein said die recess extends over an internal angle of approximately 180, terminating in two parallel arms, where a radial force is applied from outside on the outer conductor part over at least a part of the circumference of the outer conductor part, such that a cold weld is achieved.

In a method for manufacturing a wire harness, a process in which a metallic tube body is expanded in an exterior member to be an expanded state, so that an outer surface of an insulator comes into close contact with an inner surface of the exterior member is included.