Abstract: A plug connector for a hybrid cable comprises a fiber and wire holder to hold at least one optical fiber and at least one electrical conductor of the hybrid cable. The plug connector comprises at least one optical device being configured such that a light beam received from the at least one optical fiber at a first side of the at least one optical device is collimated and coupled out at the second side of the at least one optical device. The plug connector comprises an electrical contact pin to be coupled to the at least one electrical conductor of the hybrid cable. The electrical contact pin has a structure being configured to be engaged in a complimentary receptacle to mechanically fix the plug connector to the receptacle.

Abstract: Apparatus for inserting optical fibers into furcation tubes comprises a plurality duct-like channels each configured to receive one of the furcation tubes in such a way that the furcation tube is insertable from a first side of the apparatus into the duct-like channel so that a long tube section of the furcation tube can be left protruding on the first side and a short tube section of the furcation tube can protrude on an opposite second side of the apparatus. Each duct-like channel is further configured so that a portion of the long tube section becomes spread apart along a longitudinal slot of the furcation tube, thereby allowing an optical fiber to be inserted into the short tube section and extended through the furcation tube before protruding from the longitudinal slot in the long tube section.

Abstract: A cable assembly with electrical conductors and fiber optic lines includes a hybrid cable, electrical tethers, a fiber optic tether, and a joining location thereof that includes a shielding unit establishing an electrical contact between shielding of the hybrid cable and shielding of the respective electrical tether cables. The shielding unit includes a central body of an conductive material surrounding the hybrid and tether cables at the joining location, where the central body is in electrical contact with the shielding of the hybrid cable and with the shielding of each electrical tether.

Abstract: An optical adaptor for mounting to a receptacle to optically couple connectorized optical cables comprises an optical interface to optically couple a first connectorized optical cable terminated by a first optical connector and a second connectorized optical cable terminated by a second optical connector. The optical adaptor further comprises a mounting element being configured to insert the optical interface and being mountable to the receptacle. The mounting element is secured to the receptacle, when the first optical connector is mounted to the mounting element in a first state, and the mounting element is released from the receptacle, when the first optical connector is mounted to the mounting element in a second state allowing to pull the optical adaptor out of the receptacle.

Abstract: An optical adaptor for mounting to a receptacle to optically couple connectorized optical cables comprises a coupling element to provide a passageway for inserting a respective ferrule of a first and a second optical connector terminating a first and a second optical cable. The optical adaptor further comprises a mounting element to mount the first optical connector to the receptacle, the mounting element being configured to be insertable in the receptacle, and a fixing element to fix the mounting element to the receptacle. The mounting element is formed as a hollow body to receive the coupling element and configured to fix the coupling element to the receptacle.

Abstract: Apparatus for inserting optical fibers into furcation tubes comprises a plurality duct-like channels each configured to receive one of the furcation tubes in such a way that the furcation tube is insertable from a first side of the apparatus into the duct-like channel so that a long tube section of the furcation tube can be left protruding on the first side and a short tube section of the furcation tube can protrude on an opposite second side of the apparatus. Each duct-like channel is further configured so that a portion of the long tube section becomes spread apart along a longitudinal slot of the furcation tube, thereby allowing an optical fiber to be inserted into the short tube section and extended through the furcation tube before protruding from the longitudinal slot in the long tube section.

Abstract: An optical adaptor for mounting to a receptacle to optically couple connectorized optical cables comprises an assembly of an optical interface to provide an optical path between a first and a second one of the connectorized optical cables to optically couple the first and the second connectorized optical cable. The optical adaptor further comprises a mounting element formed as a hollow body to mount the assembly of the optical interface. The assembly of the optical interface is configured to be insertable in the hollow body of the mounting element. The mounting element is configured to mechanically couple the first connectorized optical cable to the mounting element so that the first connectorized optical cable is optically coupled to the optical path.

Abstract: An optical adaptor for mounting to a receptacle to optically couple connectorized optical cables comprises a coupling element to provide a passageway for inserting a ferrule of a first optical connector to terminate a first one of the connectorized optical cables and a ferrule of a second optical connector to terminate a second one of the connectorized optical cables to optically couple the first and the second connectorized optical cable. The optical adaptor further comprises a mounting element being mountable to the receptacle to hold the optical adaptor. The mounting element is configured to receive the coupling element.

Abstract: An optical adaptor for mounting to a receptacle to optically couple connectorized opticable cables comprises an assembly of an optical interface to provide an optical path between a first and a second one of the connectorized optical cables to optically couple the first and the second connectorized optical cable. The assembly of the optical interface comprises a mounting element to mount the optical adaptor to the receptacle. The mounting element is configured to receive the assembly of the optical interface and to mechanically couple the first connectorized optical cable to the mounting element so that the first connectorized optical cable is optically coupled to the first side of the assembly of the optical interface.

Abstract: Optical connector assemblies for device-to-device optical connections are disclosed. In one embodiment, an optical connector assembly includes a housing having a mating surface, an optical coupling body, a first contact pin, and a second contact pin. The optical coupling body includes an optical coupling face such that the optical coupling face is exposed at the mating surface of the housing. The optical connector assembly further includes a plurality of GRIN lenses disposed within the optical coupling body, wherein each GRIN lens has a coupling surface positioned at the optical coupling face of the optical coupling body. The first and second contact pins extend from the mating surface of the housing such that they are positioned on opposite sides of the optical coupling body. Optical connector assemblies incorporating a total-internal-reflection surface are also disclosed.

Abstract: Connector assemblies and methods are disclosed for providing sealing and strain-relief. In one embodiment, the connector assembly includes a cable assembly having an overmold portion, an inner housing, and a coupling body. The inner housing includes a sealing element for providing sealing from environmental elements and a crank for providing strain-relief for the connector assembly and inhibiting pulling forces on the cable assembly from being transmitted to the connector of the cable assembly.

Abstract: A plug connector for a hybrid cable comprises a fiber and wire holder to hold at least one optical fiber and at least one electrical conductor of the hybrid cable. The plug connector comprises at least one optical device being configured such that a light beam received from the at least one optical fiber at a first side of the at least one optical device is collimated and coupled out at the second side of the at least one optical device. The plug connector comprises an electrical contact pin to be coupled to the at least one electrical conductor of the hybrid cable. The electrical contact pin has a structure being configured to be engaged in a complimentary receptacle to mechanically fix the plug connector to the receptacle.

Abstract: Electro-optical connectors and connector systems are disclosed. In one embodiment, an electro-optical plug includes a tip connector, a ring connector, and a sleeve connector, wherein the tip connector, the ring connector, and the sleeve connector are electrically conductive. The electro-optical plug further includes a gradient-index lens co-axially disposed within at least the tip connector, wherein the tip connector has a tip window that optically exposes a coupling surface of the gradient-index lens, and an optical fiber that is co-axially disposed within at least the sleeve connector. In another embodiment, an electro-optical connector includes a plug body having a planar electrical coupling surface with an array of electrically conductive contacts, and an optical coupling surface having at least one optical window. The electro-optical connector further includes a gradient-index lens disposed within the plug body.

Abstract: Electro-optical connectors and connector systems are disclosed. In one embodiment, an electro-optical plug includes a tip connector, a ring connector, and a sleeve connector, wherein the tip connector, the ring connector, and the sleeve connector are electrically conductive. The electro-optical plug further includes a gradient-index lens co-axially disposed within at least the tip connector, wherein the tip connector has a tip window that optically exposes a coupling surface of the gradient-index lens, and an optical fiber that is co-axially disposed within at least the sleeve connector. In another embodiment, an electro-optical connector includes a plug body having a planar electrical coupling surface with an array of electrically conductive contacts, and an optical coupling surface having at least one optical window. The electro-optical connector further includes a gradient-index lens disposed within the plug body.

Abstract: Connector assemblies and methods are disclosed for providing sealing and strain-relief. In one embodiment, the connector assembly includes a cable assembly having an overmold portion, an inner housing, and a coupling body. The inner housing includes a sealing element for providing sealing from environmental elements and a crank for providing strain-relief for the connector assembly and inhibiting pulling forces on the cable assembly from being transmitted to the connector of the cable assembly.

Abstract: A cable assembly with electrical conductors and fiber optic lines includes a hybrid cable, electrical tethers, a fiber optic tether, and a joining location thereof that includes a shielding unit establishing an electrical contact between shielding of the hybrid cable and shielding of the respective electrical tether cables. The shielding unit includes a central body of an conductive material surrounding the hybrid and tether cables at the joining location, where the central body is in electrical contact with the shielding of the hybrid cable and with the shielding of each electrical tether.

Abstract: Disclosed is an electrical distribution device (10), e.g. a distribution piece, for connection to line and/or connecting devices (12) having shielding devices (18), wherein the distribution device (10) having a conductive housing (20) for forming a shielding, and at least one conductor track mount (26, 28), arranged in the housing (20), for connection of line and/or connecting devices (12).

Abstract: An electrical multiple distributor includes a housing having a modular design and including an inner housing. At least one clamping device is disposed on the housing and is configured to contact a shielded line of at least one cable outlet so as to connect the at least one cable outlet. At least one receiving contour is disposed at a connection position and is configured to accommodate a connecting sleeve so as to connect at least one connector. An electromagnetic shielding device is disposed on the housing, and a protective device is disposed on the housing and is configured to protect against at least one of moisture and dust. At least two electrical connections are disposed in the housing, and at least one distribution system is disposed in the housing and is configured to selectively interconnect the at least two electrical connections, the at least one distribution system being positionable by the inner housing.

Abstract: An electrical multiple distributor includes a housing having a modular design and including an inner housing. At least one clamping device is disposed on the housing and is configured to contact a shielded line of at least one cable outlet so as to connect the at least one cable outlet. At least one receiving contour is disposed at a connection position and is configured to accommodate a connecting sleeve so as to connect at least one connector. An electromagnetic shielding device is disposed on the housing, and a protective device is disposed on the housing and is configured to protect against at least one of moisture and dust. At least two electrical connections are disposed in the housing, and at least one distribution system is disposed in the housing and is configured to selectively interconnect the at least two electrical connections, the at least one distribution system being positionable by the inner housing.

Abstract: A method transforms an image from polar coordinates into Cartesian coordinates. Therefore, the target image in Cartesian coordinates is subdivided into triangles defined by the vertices given in Cartesian coordinates. The respective polar coordinates are coded into attributes and these attributes are attached to each vertex. The attributes of any coordinates within the triangle are calculated by performing a bilinear interpolation on a graphics card and the polar coordinates are calculated from these attributes. Finally, the characteristics of the coordinates of the image in polar coordinates are transferred to the corresponding coordinates of the target image given in Cartesian coordinates. A method also consistently displays single ore multiple radar scan images with additional geographical data in one display plane. These methods may be performed by a computer program and implemented in a radar scan converter.