Abstract: An optical device for serializing data signals in a plurality of parallel channels is disclosed, including: (a) a plurality of waveguides adapted to conduct light signals of a predetermined wavelength; and (b) a nonlinear optical element having a refractive index and defining an optical path thereon adapted and configured to conduct a control light pulse along the optical path, wherein a portion of each of the plurality of waveguides is adjacent to or in contact with the nonlinear optical element at a different portion along the optical path; wherein the refractive index along the optical path is substantially altered where the control pulse is located such that the relative phase of the light signals of the predetermined wavelength is altered only where the signal is substantially coincident with the control pulse.

Abstract: The present invention consists of a method and a structure formed by such method relating to optical fibers. Specifically, the invention consists of a chemical mill process for shaping the end of a fiber and thereby simultaneously forming both lens and precision mounting region. Also described is a self-aligning structure with integral lens. Both features improve light coupling. The lens focuses light energy entering and exiting the fiber. The precision mounting region facilitates alignment of fiber at couplings.

Abstract: An asymmetric de-multiplexer/multiplexer includes: at least a first, second, and third optical fibers; at least one lens optically coupled to the first, second, and third optical fibers; at least one diffraction grating optically coupled to the at least one lens at a side opposite to the first, second, and third optical fibers; and a reflector array optically coupled to the at least one lens at a side opposite to the at least one diffraction grating. The reflector array includes: a substrate, and a plurality of reflectors coupled to the substrate at a side opposite to the at least one lens, where the plurality of reflectors reflects a first subset of channels of a composite optical signal traversing the apparatus, where the subset of channels has irregular inter-channel spacings and non-uniform bandwidths. The apparatus thus is able to overcome bandwidth utilization inefficiencies of conventional regular spaced channel assignment schemes.

Abstract: An optical sensor diagnostic system utilizing a tunable Vertical Cavity Surface Emitting Laser (VCSEL) that incorporates an integrated MEMS tuning mechanism provides variable wavelength light into an optical fiber with improved wavelength scanning speed and greater simplicity of construction. Sensors, such as Bragg gratings, are disposed along the fiber in the light path. Each sensor reflects or transmits light exhibiting a characteristic amplitude feature with respect to wavelength, the wavelength position of which is affected by an environmental stimulus imposed thereon. The power of the reflected light is converted to an electrical signal by a simple detector and monitored by circuitry that detects changes in reflected power and provides output signals indicative of the environmental stimulus for each sensor.

Abstract: A GRIN fiber lens has a silica-glass core whose refractive index has a radial profile. The profile has a radial second derivative whose average magnitude in the core is less than about 1.7×10−6 microns−2 times the value of the refractive index on the axis of the GRIN fiber lens.

Abstract: A method of modifying birefringence properties of a waveguide formed within a carrier, the method comprising the steps of inducing a stress anisotropy in the waveguide and effecting a differential decrease in a first refractive index of one mode in the waveguide with respect to a second refractive index of another mode of the waveguide.

Abstract: A optical scour sensor monitors scour, including deposition and ablation, in bodies of water that may be too lossy to enable use of electrical signals. A specially configured optical fiber is inserted into the sediment and the interface between the sediment and water thereby monitored using a top-mounted control box to pulse light down the cable and capture reflected signals. The optical fiber may be armored by a soft plastic concentric shield and incorporate a micro-bend inducer for detecting minute indentations in the fiber. The presence of a non-liquid, e.g., sediment, against the cable is detected because the sediment impinges on the fiber causing an indentation therein. At each indentation a reflection is sent back to the source. Using principles of optical time domain reflectometry (OTDR), the location of the indentiation is determined. The data are fed to a remote system for processing, analysis and display.

Abstract: The opto-acoustic generator of ultrasound waves comprises an optical fiber associated to a laser-energy source, and an opto-acoustic transducer which is applied to said fiber and is designed to be impinged upon by the laser beam and to absorb partially the energy, converting it into thermal energy, thus bringing about the formation of ultrasound waves by the thermo-acoustic effect. Said opto-acoustic transducer consists of a layer or film containing prevalently graphite, which is applied on a surface of said optical fiber.

Abstract: An optical waveguide device adaptable to be coupled with one or more similar optical waveguide devices through commensurate slots on the devices, the slots guiding the ends of the respective waveguides into contact with each other, and into properly aligned optical coupling.

Abstract: An apparatus and associated method for altering the propagation constant of a region of equalizing propagation constant in an optical waveguide. The method comprising positioning an electrode of a prescribed electrode shape proximate the waveguide. An altered region of equalizing propagation constant is projected into the waveguide that corresponds, in shape, to the prescribed electrode shape by applying a voltage to the shaped electrode. The propagation constant of the region of equalizing propagation constant is controlled by varying the voltage.