Abstract: A waveguide cores consisting of a subwavelength grating permits transmission of light without diffraction in a discontinuous manner, wherein the energy is provided by field hopping between subwavelength material segments of higher index. The use of alternating segments permits design of waveguides having desired effective index, mode confinement factor, birefringence, polarization mode or mode dispersions, polarization dependent loss, thermal sensitivity, or nonlinear optical coefficient. An optical system comprises a waveguide having such a core, clad on at least one side, extending between two ends, and wavelength-limiting optical components in optical communication with the ends.

Abstract: An optical bus. Optical sub-assemblies are used to connect lengths of optical fiber to form a single optical fiber that is a bus. A master transceiver may be connected to one end of the fiber and nodes can be connected to the optical sub-assemblies. Each optical sub-assembly includes a center fiber with a mirror that enables each connector to reflect optical signals out of the fiber and that enables a node to launch optical signals on the optical bus. The optical bus can also be connected with a second transceiver that may be used to deliver optical power to the attached nodes. Some nodes include two optical subassemblies to enable bidirectional communication on the optical bus.

Abstract: An optical fiber distribution assembly is disclosed. The assembly includes an enclosure formed by a circular base and a cover joined at a waterproof seal. The base includes openings configured to accept an input cable and an output cable. The assembly also includes an inner body formed by four panel members to define four quadrants. In one example, the inner body is formed by two panel members positioned perpendicularly to one another. Disposed on the inner body are plurality of cable management structures including: radius limiters, splice trays, splitters, terminations, and connector storage holders.

Abstract: An optical fiber connector is disclosed. The optical fiber connector includes a housing, a coupler and an resilient member received in the housing. The coupler received in the housing and couples optical signals between optical fibers. The coupler includes a main portion and a flat positioning portion integrally connected to the main portion. The resilient member includes a first arm and a second arm forming a subtantially V-shaped profile, an inner surface of the resilient member is flat. The positioning portion is inserted between the V-shaped profile resilient member, and the distal end of the positioning portion is in contact to the resilient member. The resilient member is configured to apply a spring force on the coupler.

Abstract: There is provided an optical connector module in which an adhesive is interposed between a lens and a distal surface of an optical fiber, wherein the module includes a transparent positioning device and an optical fiber fixed in the positioning device. The positioning device has a lens provided to an end surface, a concave insertion portion into which the optical fiber is inserted and which is disposed so that the bottom surface in contact with the distal surface of the optical fiber is positioned opposite the lens, and a debris receiving portion that extends from the bottom surface in a radial direction of the optical fiber and has a surface continuous with the bottom surface.

Abstract: A printing apparatus performs printing on a printing medium by moving a print head relative to the printing medium in a main scanning direction, which is a width direction of the printing medium, and a sub-scanning direction that intersects the main scanning direction. The printing apparatus includes a print head that includes a plurality of nozzles configured to eject ink; an acquisition unit that acquires image data; and a dot forming unit that controls the print head so as to eject the ink to form dots corresponding to the image data on the printing medium. When suppression dots, which are dots formed to suppress bleeding, are formed on the printing medium, the dot forming unit controls the print head so that ink corresponding to the suppression dots is ejected from preceding nozzles arranged to eject ink to the printing medium earlier than other nozzles of the plurality of nozzles.

Abstract: A telecommunications assembly includes a chassis with a top wall, a bottom wall, a front opening, a rear opening, and first and second transverse sidewalls extending between the front and rear openings, the top wall and bottom walls defining slots. Upper mounting guides defining upper key slots between adjacent upper guides and lower mounting guides defining lower key slots between adjacent lower guides are mounted to the top and bottom walls. The upper and lower guides define snap-fit structures inserted into the slots defined on the top and bottom walls for mounting the upper and lower guides to the chassis. At least one of the upper and the lower mounting guides defines adapter mounts for slidably receiving fiber optic adapters through the rear opening. Fiber optic modules are slidably received within the chassis through the front opening and each module is slidably inserted into the upper and lower key slots of the chassis, each module removable from the chassis through the front opening.

Abstract: The method for filtering an optical signal comprising a plurality of channels lying on a grid of optical frequencies equally spaced by a frequency spacing and occupying an optical bandwidth, comprises: a) operating an optical filter comprising a plurality of resonators, wherein a first resonator of the plurality is optically coupled to the optical signal and the remaining resonators are optically coupled in series to the first resonator, so that a respective resonance of each one of the plurality of resonators falls within a first frequency band having bandwidth less than or equal to 15 GHz; b) operating the optical filter so as to obtain a separation between said respective resonance of at least one resonator with respect to said respective resonance of at least another different resonator, the separation being greater than or equal to 25 GHz; c) operating the optical filter so that said respective resonance of each one of the plurality of resonators falls within a second frequency band, different from the f

Abstract: An inkjet printing device includes: a flow path plate, a piezoelectric actuator and an electrostatic force applicator. The flow path plate includes an ink inlet, a pressure chamber and a nozzle. The piezoelectric actuator is configured to provide a first driving force, and the electrostatic force applicator is configured to provide a second driving force. The disclosed inkjet printing devices and methods combine piezoelectric and electrostatic techniques.

Abstract: An optical connector defining a receiving space for receiving a corresponding plug includes an insulative housing, an optical module mounted to the insulative housing, and a protecting mechanism assembled into the receiving space. The insulative housing has a front surface at a rear side of the receiving space. The optical module has a light receiving element located behind the front surface and forwardly exposed to the receiving space. The protecting mechanism has a door lying in a vertical plane in front of the front surface to shield the light receiving element along an insertion direction when the plug is not inserted into the receiving space, and moving downwardly out of the receiving space to unveil said light receiving element in said insertion direction when the plug is inserted into the receiving space.

Abstract: A method of filtering an optical signal includes operating an optical filter having resonators, each having a respective free spectral range and a respective resonance falling within a first frequency band, first tuning at least one resonator with respect to at least another resonator to obtain a separation between any resonance of at least one resonator falling within an optical bandwidth with respect to a resonance of at least another resonator nearest to the any resonance, second tuning all the resonators of the optical filter so as to move all respective resonances by a respective frequency interval greater than a frequency spacing, and third tuning the at least one resonator and the at least another resonator such that a further respective resonance of each one of the resonators falls within a second frequency band, different from the first frequency band.

Abstract: Systems and methods for the management and routing of telecommunication cables include cable trough members. Generally, the trough members include a plurality of retainer members coupled to sidewalls of the trough members. The retainer members assist in maintaining cables within an interior of the trough members.

Abstract: An optical fiber coupler is formed of a section of optical fiber that is positioned between a conventional input fiber (for example, a single mode fiber) or waveguide and a coiled optical fiber device. The adiabatic coupler is coiled (or, at least, curved) to assist in transforming a conventional fundamental mode optical signal propagating along the longitudinal axis of the input fiber to an optical signal that is shifted into a peripheral region of the coiled optical fiber. Moreover, the pitch of an inventive coiled optical fiber coupler can be controlled to assist in the adiabatic transformation process.

Abstract: A clip holds a plurality of optical fibers in an array to be inserted into a fiber optic ferrule. The clip has a base member and a lid to hold the optical fibers therebetween. A stacker block assists in making the array by aligning them in a single plane. The optical fibers are then held in alignment for stripping, cleaving and inserting into the fiber optic ferrule.

Abstract: A fluid ejecting apparatus includes a drive element that performs a driving operation when a drive waveform is applied thereto and causes a nozzle to eject fluid. A drive signal generating unit generates a first drive signal having a first drive waveform at a front section of a predetermined period and a second drive waveform at a rear section thereof. A second drive signal has a third drive waveform at a front section of the predetermined period and a fourth drive waveform at a rear section thereof. A control unit applies the first drive waveform to the drive element, which then performs a first operation, applies the fourth drive waveform to the drive element, which then performs a second operation, and applies the second drive waveform to the drive element after applying the third drive waveform thereto, so that the drive element performs a third operation.

Abstract: Provided is a semiconductor optical device, which has a buried heterostructure structure and is formed in a structure capable of reducing a parasitic capacitance to further improve characteristics thereof, and also provided are an optical transmitter module, an optical transceiver module, and an optical transmission equipment. The semiconductor optical device includes a modulator portion for modulating light input along an emitting direction and radiating the modulated light, the modulator portion including: a mesa-stripe structure, which includes an active layer and extends in the emitting direction; and a buried layer provided adjacent to each side of the mesa-stripe structure, in which a distance between a lower surface of the buried layer and a lower surface of the active layer is 20% or more of a distance between the lower surface and an upper surface of the buried layer.

Abstract: Optical interfaces that may be employed between large-core optical fibers and chip-scale optoelectronic devices. Described herein are couplers that improve the tolerance of misalignment when a single mode (SM) fiber is used as waveguide input. This enables the possibility of passive/automatic alignment and therefore reduces the production cost. The coupler also serves as a spot-size converter that reduces the spot size and is suitable for applications where a waveguide mode with small cross-section area is of particular importance. One such example can be a waveguide-based SiGe or III-V semiconductor photodetector in which the vertical size of its waveguide mode should be as small as few microns.

Abstract: The An opto-electro hybrid harness includes, at locations away from first and second connectors, a first relay segment having an EO conversion device, and a second relay segment having an OE conversion device. First and second electric cables lie between the first connector and the first relay segment and between the second connector and the second relay segment. An opto-electric hybrid cable segment lies between the first and second relay segments. An optical fiber is connected at one end to the E0 conversion device and at the other end to the OE conversion device. A first electronic wire of the first electric cable is connected at one end to the first connector and at the other end to the E0 conversion device. A second electronic wire of the second electric cable is connected at one end to the OE conversion device and at the other end to the second connector.

Abstract: A protecting device for protecting a cable having a plurality of fibers, includes a conduit which is sleeved on the cable, a distribution member, a first and second clamping members, a first and second fasteners, and a resilient sleeve. The conduit has a first threaded portion on one end of the conduit. The distribution member is being sleeved on the cable, the first clamping member has a plurality of clamping claws for clamping the distribution member; and the first fastener has a restricting portion; the distribution member and the first clamping member are being received in the conduit, the first fastener is engaged with the first threaded portion of the conduit. The plurality of clamping claws of the first clamping member are urged by the restricting portion to tightly clamp the distribution member and the cable.

Abstract: A plug housing for accommodating a plug for connecting to the adapter, includes a housing body having an inside surface, the inside surface forming a through hole accommodating the main body of the plug, a slope portion formed on the inside surface and configured to cause the main body of the plug to move forward by a reaction force received from a second lever formed on the side surface of the plug when the main body of the plug is accommodated in the through hole and the second lever is pushed down by the slope portion, and a restrict portion formed on the inside surface and configured to restrict the forward movement of the main body of the plug.