Abstract: The present disclosure includes methods, devices, and systems for zinc oxide diodes for optical interconnections. One system includes a ZnO emitter confined within a circular geometry in an oxide layer on a silicon substrate. An optical waveguide is formed in the oxide layer and has an input coupled to the ZnO emitter. A detector is coupled to an output of the optical waveguide.

Abstract: A heads-up display system includes a liquid crystal display unit that can change optical characteristics in accordance with a video signal. The light modulated by the liquid crystal display unit is projected on a surface of a transparent plate that can reflect the light so as to realize a projection display. The light projected on the transparent plate is polarized light having a transmission axis extending in a direction parallel to a line defining the center with respect to incident light and reflective light of the transparent plate.

Abstract: The present invention provides a liquid crystal display module or a liquid crystal display device which can prevent the generation of display irregularities. In the liquid crystal display module which includes a liquid crystal display panel, a frame-like mold frame, alight guide plate, and a reflection sheet, the liquid crystal display panel is arranged on an upper side of the mold frame, the light guide plate and the reflection sheet are arranged on a lower side of the mold frame, the reflection sheet is adhered to the mold frame using an adhesive agent which is formed on at least two sides of the reflection sheet which face each other in an opposed manner, and a portion of one side of the reflection sheet on which the adhesive agent is arranged has a length larger than a length of a portion of another side of the reflection sheet on which the adhesive agent is arranged.

Abstract: An optical apparatus comprises: a semiconductor substrate; a semiconductor optical device integrally formed on the substrate and having a device end face; and a low-index planar optical waveguide integrally formed on the semiconductor substrate at the device end face. The waveguide is end-coupled at its proximal end to the optical device through the device end face and is arranged so as to comprise a waveguide mode converter. The waveguide is arranged at its distal end to transmit or receive an optical signal through its distal end to or from another low-index optical waveguide end-coupled with the integrally-formed waveguide and assembled with the integrally-formed waveguide, optical device, or substrate. The optical apparatus can further comprise a discrete low-index optical waveguide assembled with the integrally-formed waveguide, optical device, or substrate so as to be end-coupled with the integrally-formed waveguide at its distal end.

Abstract: An integrated array for optoelectronic components in an optical communications system is disclosed. The integrated array incorporates a plurality of optoelectronic modules, such as optical transceivers, in a compact, integrated geometry for positioning within an optical device, such as an optical switch or router. In one embodiment, the integrated array includes a component structure comprised of a plurality of optical transceiver sub-modules, each having dual optical ports. The component structure is integrated as a single structure to minimize the spacing between each transceiver sub-module. This in turn increases the optical port density of the integrated array. The integrated array is received by a cage that is attached to a host board within the optical device. A latching mechanism is included to selectively secure the integrated array within the cage.

Abstract: Distortion of the temperature control element and the package by thermal deformation or mechanical deformation is prevented from being transmitted to the optical element as stress, and at the same time, constant temperature control of the optical element is realized. An optical element unit including an optical element that requires temperature control and an optical component that does not require temperature control, and a temperature control element for performing temperature adjustment of the optical element are arranged. The temperature control element performs temperature adjustment control of the optical element through a region mounted with the optical component of the optical element unit.

Abstract: An exemplary liquid crystal display device (1) includes: a first substrate (11); a second substrate (12) opposite to the first substrate, the second substrate including a bottom surface having a plurality of recesses (125) defined thereat, a plurality of reflection layers (126) filled in the recesses; a liquid crystal layer (14) between the first and second substrates; a plurality of pixel regions (13) adjacent each other and each spanning through the first substrate, the liquid crystal layer, and the second substrate, each pixel region including a reflection region (133) and a transmission region (134); and a backlight module (17) disposed adjacent to the second substrate. In each pixel region, the reflection regions correspond to portions of the bottom surface of the second substrate having the reflection layers. The transmission regions correspond to portions of the bottom surface of the second substrate that do not have the reflection layers.

Abstract: An optical device containing a four-port optical mixer capable of distributing the optical power presented at either or both of two input ports to specified ratios in two output ports.

Abstract: There is provided a method for fabricating a wiring board including: a mounting step of mounting a light transmitting member, the mounting step including: an arranging step of holding the light transmitting member by light transmitting holder to arrange the light transmitting member at a wiring board main body, and a step of curing a photo-curing resin material between the light transmitting member and the wiring board main body by light transmitted through the light transmitting member and the holder.

Abstract: Methods and apparatus for dither control of a micromirror using a servo control loop in an optical switching apparatus, an optical switching apparatus and optical network are disclosed. A servo control loop may use dither tone having two or more frequency components to dither an output driver that controls the position of a micromirror in an optical switch. The two components may be demodulated from an optical signal deflected by the micromirror. The optical signal may be fed into two band-pass filters. Each band-pass filter may have a pass band centered on a different one of the two frequency components. The envelope detector may compare the envelopes of the band-pass filter outputs. If the envelopes differ by more than a set threshold the output of the envelope detector may be forced to zero. Otherwise, the output of the envelope detector may be the sum of the two band-pass filter outputs.

Abstract: An optical fiber drop receiving device may include a housing assembly including a duct entry port for receiving a drop conduit. A drop receiving cylinder may be rotatably mounted in the housing assembly and connected to the duct entry port. The drop receiving cylinder may be configured to receive a fiber drop and a flow of pressurized air from the duct entry port. The drop receiving cylinder may include an escape port for providing an outlet for the flow of pressurized air. The flow of pressurized air through the escape port may cause the drop receiving cylinder to rotate within the housing assembly. The rotation of the drop receiving cylinder may enable winding of the received fiber drop inside the drop receiving cylinder.

Abstract: Provided are a light guide panel and a display device employing the same. The light guide panel includes: an incidence surface facing a plurality of light sources separated apart a predetermined distance; at least one dark portion reducing unit that is formed on the incidence surface between adjacent pairs of the slight sources and at both edges of the incidence surface, and reflects the light incident from the light sources to reduce the creation of dark portion units; an upper surface transmitting a portion of incident light and reflecting the rest of the incident light; and a lower surface facing the upper surface and reflecting the light incident from the incidence surfaces and dark portion reducing units.

Abstract: A protecting cover bends a signal transfer film connected to a display panel toward a sidewall of a container and includes a first adhesive region attached to a sidewall of a front case, a second adhesive region attached to a bottom plate of the container and a guide region between the first and the second adhesive regions. A boundary line between the guide region and the second adhesive region is spaced apart from an edge of the second adhesive region by a first gap in a position corresponding to the signal transfer film and is spaced apart by a second gap that is wider than the first gap in a position corresponding to a space between the signal transfer films.

Abstract: An exemplary flat panel display (1) includes a display module (11), a chassis (13) secured to the display module, a connecting piece (15) attached to the chassis, and a button module (14) attached to the connecting piece. The flat panel display can be efficiently manufactured with a reduced overall cost.

Abstract: There is provided a thermal sensing fiber including a semiconducting element having a fiber length and characterized by a bandgap energy corresponding to a selected operational temperature range for the fiber in which there can be produced a change in thermally-excited electronic charge carrier population in the semiconducting element in response to a temperature change in the selected temperature range. At least one pair of conducting electrodes is provided in contact with the semiconducting element along the fiber length, and an insulator is provided along the fiber length.

Abstract: A goggle includes a lens assembly which comprises a front lens, a rear lens spaced apart from the front lens, and a liquid crystal device disposed on one of the lenses. The goggle includes a frame, which defines an aperture and a peripheral channel. The peripheral channel receives the front lens and the rear lens is positioned rearward of the channel so that the aperture receives the lens assembly. A power unit includes a battery and a drive circuit, wherein the drive circuit is connected to a pair of prongs that are electrically connectable to the liquid crystal device for operation thereof. The power unit provides a master switch connected to the battery to control application of power to the drive circuit, and a state change switch to control application of power from the drive circuit, through the prongs, to the liquid crystal device.

Abstract: A method of terminating a fiber in a connector, the method comprising: (a) securing a stripped fiber to a device; (b) while the fiber is secured to the device, cleaving the fiber to produce a cleaved fiber; (c) securing a connector having a stub to the device; (d) while the connector and the fiber are secured to the device, inserting the cleaved fiber into the connector such that the cleaved fiber mates with the stub; (e) and securing the fiber to the connector.

Abstract: In an OCB mode liquid crystal display device, a first phase layer that causes a retardation in an in-plane azimuth direction is disposed between a first polarizing layer and a liquid crystal layer such that a slow axis of the first phase layer intersects at right angles with an absorption axis of the first polarizing layer, a second phase layer that causes a retardation in an in-plane azimuth direction is disposed between a second polarizing layer and the first phase layer such that a slow axis of the second phase layer intersects at right angles with an in-plane azimuth direction in which liquid crystal molecules are inclined, and a third phase layer, which has an optical axis in a normal direction of the liquid crystal display device and has, as a whole, a negative uniaxial function, is disposed between the second polarizing layer and the first phase layer.

Abstract: An apparatus and a method for steering optical frequency beams using nanowire. A method includes providing one or more nanowire waveguide arrays, generating an optical frequency beam, wherein the optical frequency beam is incident on the one or more nanowire waveguide arrays, controlling the one or more nanowire waveguide arrays to produce a phase delay in the optical frequency beam as it traverses the nanowire waveguide array, wherein the phase delay causes the optical frequency beam to deflect upon exiting the one or more nanowire waveguide arrays, and steering the optical frequency beam exiting the one or more nanowire waveguide arrays by increasing or decreasing the phase delay, wherein the angle of deflection of the exiting optical frequency beam is determined by the amount of phase delay.

Abstract: This invention provides a bistable liquid crystal device. The bistable liquid crystal device includes a first substrate having thereon a first conductive layer and a first alignment layer; a second substrate having thereon a second conductive layer and a second alignment layer; and a liquid crystal layer sandwiched between the first and second alignment layers. The first alignment layer induces a first pretilt angle ?1 in the range of 20°-65° between the liquid crystal layer in contact with the first alignment layer. The second alignment layer induces a second pretilt angle ?2 in the range of 20°-65° between the liquid crystal layer in contact with the second alignment layer. The liquid crystal layer is capable of maintaining a stable bend state or a stable splay state at zero bias voltage and is switchable between the stable bend state and the stable splay state when a switching energy is applied in operation to the liquid crystal layer.