Abstract: A signal transmission line, includes: a coaxial electrical connector comprising a coaxial electrical connector inner conductor and a coaxial outer conductor; a coaxial cable comprising a coaxial inner conductor and a coaxial outer conductor; and a section of resistive cable disposed between the coaxial cable and the coaxial connector, the section of resistive cable comprising an electrically thin resistive layer disposed between the coaxial cable inner conductor and a section outer conductor. The coaxial cable inner conductor is fastened to the coaxial electrical connector inner conductor.

Abstract: A signal transmission line, includes: a coaxial electrical connector comprising a coaxial electrical connector inner conductor and a coaxial outer conductor; a coaxial cable comprising a coaxial inner conductor and a coaxial outer conductor; and a section of resistive cable disposed between the coaxial cable and the coaxial connector, the section of resistive cable comprising an electrically thin resistive layer disposed between the coaxial cable inner conductor and a section outer conductor. The coaxial cable inner conductor is fastened to the coaxial electrical connector inner conductor.

Abstract: Methods and systems to reduce power consumption in data centers are disclosed. For example, a system includes a network switch configured to communicate high bandwidth communications to one or more servers. The system also includes one or more mode-suppressing coaxial cables coupling the network switch to the one or more servers. The one or more mode-suppressing coaxial cables are also configured to transport the high bandwidth communications between the network switch and the one or more servers.

Abstract: Deriving an optical property of a device under test includes generating a cavity light beam along a first optical path in external cavity, selecting a wavelength of the cavity light beam of light by means of a filter arrangement within the external cavity, providing an optical stimulus signal to a device under test by splitting at least a fraction of the cavity light beam, providing an optical response signal from the DUT or a signal derived there form back to the external cavity, so that said signal is passed over a second optical path passing the filter arrangement spatially different to the first optical path in order to generate a filtered optical response signal, and providing said filtered optical response signal to a detector unit.

Abstract: A receiver and method for using the same to process optical signals is disclosed. The receiver includes an optical coupler and a polarization dependent beam splitter. The optical coupler combines an input signal and a local oscillator signal into a first combined signal. The optical coupler includes a polarization filter that operates on the local oscillator to provide a linearly polarized signal having a predetermined LO polarization direction.

Abstract: An optical attenuator having a multi-mode waveguide segment and a perturbation element. An incident single-mode optical signal is converted to a multi-mode optical signal in the multi-mode waveguide segment. The optical attenuator couples incident light into higher order modes of the multi-mode waveguide segment resulting in attenuation of the incident optical signal.

Abstract: An optical attenuator having a multi-mode waveguide segment and a perturbation element. An incident single-mode optical signal is converted to a multi-mode optical signal in the multi-mode waveguide segment. The optical attenuator couples incident light into higher order modes of the multi-mode waveguide segment resulting in attenuation of the incident optical signal.

Abstract: Optical packaging assemblies and methods of making the same are described. In one aspect, an optical packaging assembly includes a package housing, a hermetically sealed optical device housing, and an optical fiber alignment assembly. The package housing includes an optical fiber feedthrough and a package electric feedthrough. One or more optical fibers extend through the optical fiber feedthrough. The hermetically sealed optical device housing is mounted within the package housing and includes an optical window and a device electric feedthrough that is electrically connected to the electric feedthrough of the package housing. At least one optical device is mounted within the hermetically sealed optical device housing in optical alignment with respect to the optical window.

Abstract: Optical packaging assemblies and methods of making the same are described. In one aspect, an optical packaging assembly includes a package housing, a hermetically sealed optical device housing, and an optical fiber alignment assembly. The package housing includes an optical fiber feedthrough and a package electric feedthrough. One or more optical fibers extend through the optical fiber feedthrough. The hermetically sealed optical device housing is mounted within the package housing and includes an optical window and a device electric feedthrough that is electrically connected to the electric feedthrough of the package housing. At least one optical device is mounted within the hermetically sealed optical device housing in optical alignment with respect to the optical window.