Abstract: An optical fiber holder for holding an optical fiber includes: a holder main body; and a groove part that is capable of holding a part of the held optical fiber. The optical fiber holder has an adjustment mechanism that is capable of adjusting a position of the groove part with respect to the holder main body in a state where the groove part is placed on the holder main body.

Abstract: A grating-coupled light guide concentrates light and diffractively redirects the concentrated light at a non-zero propagation angle as guided light having a predetermined spread angle. The grating-coupled light guide includes a light guide, an optical concentrator, and a grating coupler. The optical concentrator is configured to concentrate light from a light source as concentrated light and the grating coupler is configured to diffractively redirect the concentrated light into the light guide as the guided light. Characteristics of the optical concentrator and grating coupler are configured in combination to determine the non-zero propagation angle and predetermined spread angle. A grating-coupled display system further includes an array of light valves configured to modulate emitted light as a displayed image.

Abstract: Apparatus and devices to monitor optical power within optical fibers in a substantially non-invasive fashion are disclosed. Optical monitors are comprised of low leakage junctions within very compact optical junctions which each confine the leakage within a very small local volume but also include photodiode means to ascertain signal amplitude. Multiplexing circuits for different groupings of lines enables automated monitoring of optical status across a communication network.

Abstract: An object is to provide a highly versatile optical fiber local-light detection apparatus capable of supporting various types of coated optical fibers.

Abstract: An integrated circuit (IC) device includes an optical IC substrate, a local trench inside the optical IC substrate, and a photoelectronic element including a photoelectric conversion layer buried inside the local trench. The photoelectric conversion layer is buried inside the local trench in the optical IC substrate to form the photoelectronic element. Thus, the IC device may inhibit warpage of the optical IC substrate.

Abstract: A fusion splicer for fusion-splicing a first group of optical fibers and a second group of optical fibers by arc discharge is disclosed. The fusion splicer includes first and second electrode rods, first and second fiber holding parts, and a first shield. The electrode rods generate the arc discharge therebetween. The first fiber holding part has a first plurality of V-grooves positioning the first group of optical fibers. The second fiber holding part has a second plurality of V-grooves positioning the second group of optical fibers. The first shield is located between the first and second plurality of V-grooves and the first electrode rod in a direction along a center line connecting a tip of the first electrode rod to a tip of the second electrode rod. The first shield is formed of an insulating material having heat resisting properties withstanding 1000 or more degrees Celsius.

Abstract: A nano-opto-electro-mechanical System (NOEMS) phase shifter is described. The NOEMS may include a multi-slot waveguide structure suspended in air. The multi-slot waveguide structure may include three or more waveguides separated from each other by slots. The width of the slots may be sufficiently small to support slot modes, where a substantial portion of the mode energy is within the slots. For example, the slots may have widths less than 200 nm or less than 100 nm. The multi-slot waveguide structure may be disposed in a trench formed though the upper cladding of a substrate. An undercut may be formed under the multi-slot waveguide structure to enable free motion of the structure. NOEMS phase modulators of the types described herein may be used in connection with photonic processing systems, telecom/datacom systems, analog systems, etc.

Abstract: The invention relates to a method for producing an optical fiber coupler, having the following method steps: combining two or more light-guiding fibers (1, 2, 3) to form a fiber bundle; introducing the fiber bundle into a capillary (4); collapsing the capillary (4) onto the fiber bundle surrounded by the capillary. It is the object of the invention to provide an improved method for producing an optical fiber coupler. The method is intended to enable the positioning of the fibers within the capillary to be as precise as possible. At the same time, it should be possible to implement the method with comparatively little effort. To this end, the invention proposes that at least one of the fibers (1, 2, 3) is connected at the end to a guide body (5, 5?) whereof the diameter in the direction transversely to the longitudinal extent of the fiber (1, 2, 3) is larger than the diameter of the fiber (1, 2, 3) and smaller than the internal diameter of the capillary (4).

Abstract: Disclosed herein are configurations for fiber optic endoscopes employing fixed distal optics and multicore optical fiber.

Abstract: A fiber optic rotary connection having first and second elements rotatable relative to each other, the second element having a first subassembly rotatable about a first axis, a second subassembly rotatable about a second axis not parallel to the first axis, and first and second collimators, the first element having third and fourth collimators, one of the second and fourth collimators orientated coincident with the first rotational axis, the other of the second and fourth collimators orientated parallel to the first rotational axis, one of the first and third collimators orientated coincident with the second rotational axis, the other of the first and third collimators orientated parallel to or coincident with the second rotational axis, whereby an optical signal may be transmitted across a rotary interface between the first and second elements in a first optical path and an optical signal may be transmitted across the rotary interface in a second optical path.

Abstract: A slab waveguide, comprising a plate having parallel surfaces and a cascade light splitting film. The plate is used for receiving and transmitting incident waveguide light which bears a transmitted image. The splitting film is disposed in the plate, intersects the upper and lower surface of the plate, and is used for reflecting the incident waveguide light out of the slab waveguide to form an actual image. In order to avoid mirror image coincidence, the waveguide needs to satisfy: |arcsin(n×sin(90°?4a+b))?arcsin(n×sin(90°?2a?b))1>2?, wherein a is an inclined angle between the cascade light splitting film and the lower surface of the plate, b is an inclined angle between central image light of the incident waveguide light and the lower surface of the plate, ? is an image display viewing angle of the transmitted image, and n is the refractive index of the plate.

Abstract: A semiconductor device is provided. The semiconductor device includes a silicon nitride waveguide in a first dielectric layer over a substrate. The semiconductor device includes a semiconductor waveguide in a second dielectric layer over the first dielectric layer. The first dielectric layer including the silicon nitride waveguide is between the second dielectric layer including the semiconductor waveguide and the substrate.

Abstract: An optical connector includes a housing having a resilient member and an optical ferrule. The optical ferrule includes a plurality of attachment areas for receiving and securing a plurality of optical waveguides and a light redirecting side for changing a direction of light received from an optical waveguide. The optical connector is configured such that when an optical waveguide is received and secured in any of the attachment areas and light from the optical waveguide propagates along an optical path, the resilient member is not in the optical path. When the optical ferrule mates with a mating optical ferule, the resilient member is resiliently deformed to resiliently force the optical ferrule against the mating optical ferrule.

Abstract: A non-rotary joint for connecting a static component to a rotatable component includes an adapter on a rotatable part. A motor is joined to rotate the rotatable part. A connector is joined to the static component. The connector can be moved by an actuator from a first position joined with the adapter to a second position positioned away from the adapter. A controller is joined to control the motor and the actuator. The controller signals the actuator to move to the second position when the motor is activated and signals the actuator to move to the first position when said motor is deactivated. In a practical embodiment, the non-rotary joint makes a connection between a static signal carrier and a cable on a winch drum.

Abstract: A factory processed fiber optic ferrule assembly and field installable cable system are configured to pass through tight, microducts when routed to a demarcation point. A connector housing attaches to the fiber optic ferrule assembly at the demarcation point (or after leaving the tight, microducts) to form a connectorized end of the optical fiber. A fiber tip is protected before leaving the factory until connection is desired.

Abstract: The subject matter of this specification can be embodied in, among other things, a method that includes separating, from a few mode optical fiber, a collection of backscattered Rayleigh signals based on a vibration of the few mode optical fiber at a vibration frequency at a first location along the few mode optical fiber, separating, from the few mode optical fiber, a collection of backscattered Stokes Raman signals and Anti-Stokes Raman signals based on a temperature of the few mode optical fiber at a second location along the few mode optical fiber, detecting the separated Rayleigh signals and Raman signals, determining, based on detecting the collection of backscattered Rayleigh traces, at least one of the first location, the vibration frequency, and an amplitude of the vibration, and determining, based on the detecting the collection of backscattered Raman signals, the temperature at the second location.

Abstract: Disclosed is an invention related to a wavelength selective switch for multiple units.

Abstract: An eyepiece waveguide for an augmented reality. The eyepiece waveguide can include a transparent substrate with an input coupler region, a first orthogonal pupil expander (OPE) region, and an exit pupil expander (EPE) region. The input coupler region can couple an input light beam that is externally incident on the input coupler region into at least a first guided light beam that propagates inside the substrate. The first OPE region can divide the first guided beam into a plurality of replicated, spaced-apart beams. The EPE region can re-direct the replicated beams from the first OPE region such that they exit the substrate. The EPE region can have an amount of optical power.

Abstract: A splice assembly for a fiber optic cable that has first and second fiber optic cable sections. The splice includes a filament alignment member configured to align an end portion of a first filament section of the first fiber optic cable section with an opposed end portion of a second filament section of the second fiber optic cable section; a first spring positioned adjacent the first end of the filament alignment member; a second spring positioned adjacent the second end of the filament alignment member; and a housing having a passage in which the first spring, filament alignment member and second spring are longitudinally positioned. The filament alignment member is longitudinally moveable relative to the housing by compression of one of the springs in a direction of travel of the filament alignment member against a corresponding stop feature.

Abstract: An apparatus includes an electronic circuit, an electro-acoustic transducer and a coupler. The electronic circuit is configured to receive data to be transmitted over an optical cable, and to convert the data into a modulating signal. The electro-acoustic transducer is configured to convert the modulating signal into an acoustic wave. The coupler is configured to be mechanically coupled to a section of the optical cable, and to apply to the section a longitudinal stretching force that varies responsively to the acoustic wave, so as to modulate the data onto an optical carrier traversing the optical cable.