Abstract: A hermetically sealed ferrule includes one or more walls cooperating to enclose a volume. At least one of the walls defines an orifice permitting passage to the enclosed volume. A fiber optic ribbon passes through the orifice to the enclosed volume. The fiber optic ribbon includes a plurality of optical fibers with a protective coating surrounding each of the optical fibers. Each optical fiber is exposed where it passes through the orifice. A low-temperature melting point glass seals a space between the exposed optical fibers and the region of the wall defining the orifice. A first epoxy layer extends between the fiber optic ribbon, an outer surface of the region of the wall defining the orifice, and the low-temperature melting point glass. A second epoxy layer extends between the fiber optic ribbon, an inner surface of the region of the wall defining the orifice, and the low-temperature melting point glass.

Abstract: A substantially planar fan-out circuit that receives a set of signals at one end and conducts the signals via a set of waveguides to an opposite end of the circuit. The intensity of at least one of the optical signals is detected with an optical detector integrated into the optical circuit. The detected optical signal is attenuated with a variable optical attenuator integrated into the optical circuit. The variable optical attenuator effects an attenuation level based upon an output of the optical detector. The optical signals are delivered from the second end of the optical circuit, so that the optical signals are either more or less dispersed at the second end of the optical circuit than at the first end.

Abstract: An optical multiplexer and demultiplexer for dense wavelength division multiplexed (“DWDM”) fiber optic communication systems is disclosed. As a multiplexer, the device functions to spatially combine the optical signals from several laser sources (each of which is a different wavelength) and launch the spatially combined laser beams into a single optical fiber. As a demultiplexer, the device functions to spatially separate the different wavelengths of a wavelength division multiplexed optical link and launch each of the different wavelengths into a different optical fiber. In either embodiment, the device includes both bulk optic and integrated optic components. The spatial separation or spatial combination of laser beams of different wavelength is achieved with the use of bulk diffraction gratings.

Abstract: An optical multiplexer and demultiplexer for dense wavelength division multiplexed (“DWDM”) fiber optic communication systems is disclosed. As a multiplexer, the device functions to spatially combine the optical signals from several laser sources (each of which is a different wavelength) and launch the spatially combined laser beams into a single optical fiber. As a demultiplexer, the device functions to spatially separate the different wavelengths of a wavelength division multiplexed optical link and launch each of the different wavelengths into a different optical fiber. In either embodiment, the device includes both bulk optic and integrated optic components. The spatial separation or spatial combination of laser beams of different wavelength is achieved with the use of bulk diffraction gratings.

Abstract: An optical multiplexer and demultiplexer for dense wavelength division multiplexed (“DWDM”) fiber optic communication systems is disclosed.. As a multiplexer, the device functions to spatially combine the optical signals from several laser sources (each of which is a different wavelength) and launch the spatially combined laser beams into a single optical fiber. As a demultiplexer, the device functions to spatially separate the different wavelengths of a wavelength division multiplexed optical link and launch each of the different wavelengths into a different optical fiber. In either embodiment, the device includes both bulk optic and integrated optic components. The spatial separation or spatial combination of laser beams of different wavelength is achieved with the use of bulk diffraction gratings.

Abstract: An optical multiplexer and demultiplexer for dense wavelength division multiplexed (“DWDM”) fiber optic communication systems is disclosed. As a multiplexer, the device functions to spatially combine the optical signals from several laser sources (each of which is a different wavelength) and launch the spatially combined laser beams into a single optical fiber. As a demultiplexer, the device functions to spatially separate the different wavelengths of a wavelength division multiplexed optical link and launch each of the different wavelengths into a different optical fiber. In either embodiment, the device includes both bulk optic and integrated optic components. The spatial separation or spatial combination of laser beams of different wavelength is achieved with the use of bulk diffraction gratings.

Abstract: A method and apparatus for automatically providing for both multiplexing and independent external modulation of two or more wavelengths emitted by one or more multi-longitudinal mode laser(s) or other light source. The present invention uses an integrated optics device chip to enable coupling of the dispersed wavelengths into separate electro-optic modulators which encode each of the carrier wavelengths with a different signal. Accordingly, the volume of data which can be transmitted over an optical fiber network is increased. The carrier wavelengths can be transmitted over single or multi-mode optical fibers.