Abstract: Optical devices, components and methods for mounting optical fibers and for side-coupling light to/from optical fibers using a modified silicon V-groove, or silicon V-groove array, wherein V-grooves, which are designed for precisely aligning/spacing optical fibers, are “recessed” below the surface of the silicon. Optical fibers can be recessed below the surface of the silicon substrate such that a precisely controlled portion of the cladding layer extending above the silicon surface can be removed (lapped). With the cladding layer removed, the separation between the fiber core(s) and optoelectronic device(s) can be reduced resulting in improved optical coupling when the optical fiber silicon array is connected to, e.g., a VCSEL array.

Abstract: An exemplary bus system (50) is used to transmit data between electrical components (61, 62, 63) in an electronic device. The bus system includes a plurality of optical fibers (51), a plurality of emitters (52) and a plurality of sensors (53). The optical fibers are used to connect the electrical components to one another. A respective one of the emitters and a respective one of the sensors are disposed at each end of each of the optical fibers. Each end of each of the optical fibers with the emitter and the sensor is configured to be connected to an electrical component. An electronic device employing the bus system is also provided.

Abstract: The present invention provides cells which are capable of transmitting both optical information and electrical signals when connected with each other, and a packaging system in which these cells are connected. A first connector and a second connector are formed on each cell. These two connectors are configured complementary to each other. When two cells are pressed against each other with the first connector of one of the cells facing the second connector of the other, electrical connectors engage with each other, whereby the cells are connected electrically and mechanically. A first optical device and a second optical device are also disposed in complementary positions. When the cells are connected electrically and mechanically, the tip of the first optical device and the tip of the second optical device are brought into contact with each other, allowing an optical signal to be transmitted.

Abstract: An integrated fiber optic assembly includes some of the active components that are otherwise found in a typical transceiver. For example, a transmitter optical assembly includes a laser source, a laser driver, and a component for administering diagnostic data. A receiver optical assembly includes a photo-diode an optical converter, such as a transimpedance amplifier, and a processing control that can administer, for example diagnostic data associated with the receiver optical assembly. A combination optical assembly includes a photo-diode and a laser source, as well as many of the active components for driving, operating, or administering the laser source. In part since the active components can be placed in close proximity to each other, electrical impedance is reduced that would otherwise be present in a typical transceiver and optical subassembly.

Abstract: An optical module 1 comprises a first optical element F1, a first light receiving subassembly PD1, a second optical element F2, a second light receiving subassembly PD2, a light emitting subassembly LD3 for generating light, and a light transmitting part 3 optically coupled to the first optical element. The light emitting subassembly LD3, the first optical element F1, the second optical element F2 and the first light receiving subassembly PD1 are arranged along a predetermined plane S1. The light emitting subassembly LD3, the first optical element F1, the second optical element F2, and the second light receiving subassembly PD2 are arranged along another predetermined plane S2. The predetermined plane S1 intersects at a predetermined angle with the other predetermined plane S2.

Abstract: An optical module device includes an optical module having leads, a print substrate and a flexible substrate including a first region having a center and a peripheral areas, a second and a third region, the flexible substrate including first through-holes corresponding to the leads in the center area, a terminal and a metalized trace formed in the second and third regions respectively, and a protection layer formed on its surface at the peripheral area and in the third region, wherein the flexible substrate further includes two second through-holes in the peripheral area, which is a location close to the third region, wherein the flexible substrate is bent along a line coupling the two second through-holes, and wherein the flexible substrate at it first region is fixed to the second end member by adhesive material injected into the second through-holes.

Abstract: An image presentation device (100) with an associated optical light engine includes one or more semiconductor light emitting diodes or other such devices (122, 124, 126) that are combined to provide a source of light to a micro-display panel (150). Light integrators (128), preferably shaped to correspond to the shape of the light emitting devices, are located such that a portion of each terminal is positioned adjacent to or in direct contact with the light emitting surface of the semiconductor dies.

Abstract: A cable management system is provided that is configured to be located between adjacent equipment racks, while being vertically oriented to extend upward along a narrow space between the adjacent equipment racks. The cable management system comprises a main panel extending along a vertical longitudinal axis, the main panel having a series of module cutouts provided therein and oriented to extend along the longitudinal axis. The system further includes inter-bay functional modules secured in at least two of the module cutouts. The inter-bay functional modules include at least two of a fiber spool module, a patch panel module and a dispersion compensation module. The main panel includes a front wall having the module cutouts formed therein. The front wall is integrally joined with side flanges extending rearward therefrom to form a channel cross-section.

Abstract: An optical module and chassis incorporating “keying” features that ensure the correct insertion of the module into a given chassis, thereby preventing damage to the module and/or the system to which the chassis is connected.

Abstract: A device for coupling the light of multiple light sources (2, 3) that substantially consists of a reflectance surface (10, 11) for one or more of said light sources (2, 3) and at least one integration rod (14) having an incident surface (15), whereby the reflectance surfaces (10, 11) are positioned in light bundles (12) emitted by the light sources (2, 3) between said light sources (2, 3) and said integration rod (14); whereby the spot of each light source (2, 3) at its focal point has a surface that is smaller than the surface of said incident surface (15); and whereby said light bundles (12) enter the integration rod (14) at different parts of its incident surface (15).

Abstract: A high performance and small-scale circuitry substrate is described. The circuitry substrate includes a dielectric layer, a return plane attached to a bottom surface of the dielectric layer, and a plurality of return paths (ground) and signal lines that are attached to a top surface of the dielectric layer. The return paths on the top surface are connected to the return plane on the bottom surface by wrapping around at least one edge of the dielectric material. Return paths on the top layer can also separate each pair or adjacent signal lines. The circuitry substrate can be advantageously used to form an optoelectronic module.

Abstract: A pulling structure for an optical transceiving module is disclosed. The pulling structure includes a latch base, a latch, a linking member, and a pulling rod. The latch base is mounted on the optical transceiving module. The latch is mounted in the latch base. The linking member is coupled to the latch to enable the latch to move along a particular direction. The pulling rod is pivotably driving the linking member.

Abstract: The invention relates to an optical connector arrangement wherein the connector and the converter are connected by short plastic fiber sections. The aim of the invention is to provide one such connector arrangement which can be produced in a simple and cost-effective manner, can be easily and economically mounted on a circuit carrier and reliably and efficiently soldered to the conductors thereof, enables a modular assembly, and is at least partially heat-resistant during the assembly in such a way that, for example, a vibration-resistant reflow soldering can be carried out. To this end, the fiber sections are connected to a double ferrule which is fixed to the converters by means of a clamp. A false cover can be used for the transport and soldering.

Abstract: The fiber optic connector includes a housing, a first lens, a second lens, a first ferrule, a second ferrule, a first optical fiber, a second optical fiber, an o-ring, and a clip. The housing includes a collar, a mounting portion, and a groove formed in the mounting portion. The first and second lenses, and the first and second ferrules are attached to the housing. The first and second optical fibers are attached to the first and second ferrules, respectively. The first and second lenses are in optical communication with the first and second optical fibers, respectively. The o-ring is attached to the collar. The clip is mounted to the groove formed in the mounting portion of the housing. The fiber optic connector is mountable to a back-plane of a host device.

Abstract: The invention provides a fiber plate formed by arranging in mutually adjacent manner plural individual fiber plates of a same thickness so as to provide a light guiding plane larger in area than the light guiding plane of the individual one fiber plate, and a radiation image pickup apparatus utilizing such fiber plate, in which: each of the plural individual fiber plates is composed of a group of optical fibers having mutually parallel axes, and lateral faces of the plural individual fiber plates are mutually so bonded that the axes of the optical fibers thereof become mutually parallel.

Abstract: The invention is directed to a method for etching a solid state material to create a surface relief pattern. A resist layer is formed on the surface of the solid state material. The photoresist layer is holographically patterned to form a patterned mask. The pattern is then transferred into the solid state material by a dry etching process. The invention is especially useful for forming optical nanostructures. In preferred embodiments, a direct write process, such as ebeam lithography, is used to define defects and functional elements, such as waveguides and cavities.

Abstract: A telecommunications assembly includes a chassis and a plurality of fiber optic splitter modules mounted within the chassis. Each splitter module includes at least one fiber optic connector. Within an interior of the chassis are positioned at least one fiber optic adapter. Inserting the splitter module through a front opening of the chassis at a mounting location positions the connector of the splitter module for insertion into and mating with the adapter of the chassis. The adapters mounted within the interior of the chassis are integrally formed as part of a removable adapter assembly. A method of mounting a fiber optic splitter module within a telecommunications chassis is also disclosed.

Abstract: Various embodiments of the present invention provide optical multi-channel free space interconnects that provide optical channel isolation, thereby reducing crosstalk.

Abstract: An optical channel monitor assembly for simultaneously measuring the optical power levels of multiple series of dense wavelength division multiplexed channels or the like traveling on separate optical fibers in an optical communications system includes an arrayed waveguide grating router having a first side and a second side, the first side including a first plurality of ports and the second side including a second plurality of ports, the first plurality of ports in optical communication with the second plurality of ports, wherein the first side includes a first input port for collectively receiving a first series of optical channels, wherein the second side includes a first plurality of output ports for individually delivering the first series of optical channels, wherein the second side includes a second input port for collectively receiving a second series of optical channels, and wherein the first side includes a second plurality of output ports for individually delivering the second series of optical cha

Abstract: A ferrule embodiment includes a ferrule having a number of optical fibers each having an end and an optoelectric power source to convert light traveling through at least one of the optical fibers into electricity to provide power to a component.

Abstract: Embodiments of the present invention are directed to modular optical devices compatible with multiple fiber connectors. A lens block is configured such that one or more lens pins can mechanically couple to the lens block and such that the lens block can mechanically couple to a fabricated package that includes light transmitting and/or detecting components. At least one lens pin has a fiber stop configured to accept a fiber end prepared for use with a first type of fiber connector. A fiber stop disk alters the configuration of the lens pin such that the lens pin can compatibly accept a fiber end prepared for use with a second different type of fiber connector not withstanding that the fiber stop is configured to accept a fiber end prepared for use with the first type of fiber connector.

Abstract: An optical cable harness assembly and method are provided. The optical cable harness assembly includes at least one optical cable harness having a termination end; at least one electrical connector having connector pins; and at least one active connector conversion unit coupled between the termination end of the optical harness cable and the electrical connector. A method for retrofitting an optical harness assembly into an existing platform is disclosed. The method includes removing a legacy wiring harness; installing an optical harness assembly having electrical connectors and an active connector conversion unit; and testing the compatibility of connector pins of the electrical connector to the active connector conversion unit.

Abstract: A fiber waveguide optical subassembly uses the multi-mode fiber to increase the alignment tolerance between the active optical element and the waveguide. The filter is thinner to lower the dispersion due to the optical coupling gap. The subassembly further combines the optical bench to achieve passive positioning. Therefore it reduces the cost and enhances the transmission rate.

Abstract: The present invention is to provide an intelligent pluggable transceiver improving an EMI tolerance with a simple mechanism. The optical transceiver of the invention comprises upper and lower housings (11, 12), a holder (81), optical assemblies (51, 61), a cover (14), a substrate (15) and a grip (13). The optical assemblies are fixed with the upper and lower housings together with the holder with interposing the conductive elastic member. Although the rear end of the substrate exposes outside the transceiver, the shield gasket and the ground pattern on the substrate shields the contact portion between the substrate and the upper housing and between the substrate and the cover. Moreover, the grip and the latch lever installed in the lower housing, and the elastic piece realize the latching/releasing mechanism of the transceiver with the host system.

Abstract: A terminal element for fiber optic communication has an elongated body defining a body axis and having a first end from which an optical fiber extends along the body axis. The body has a second end with an angled surface offset at an angle from the body axis. The fiber extends partly through the length of the body, and terminates at a fiber end surface. The second portion has an optical entry surface registered with the fiber end surface such that light emitted from the fiber end surface enters the optical entry surface. At least one of the fiber end surface, angled surface and optical entry surface has a figured optical form with a non-planar shape.

Abstract: An optical connector for use with a light separator, the optical connector including a first portion and a second portion, the first portion being optically couplable by first optical transmitter to a first input of the light separator and by second optical transmitter to a second input of the light separator. The first and second portions are detachably couplable to couple the first and second optical transmitter to third and fourth optical transmitters, respectively, provided in or coupled to the second portion. The first and second inputs of the light separator can thereby be optically coupled to a first optical instrument coupled to the third optical transmitter and a second optical instrument coupled to the fourth optical transmitter.

Abstract: An active cable that includes an integrated electrical connector at one end and an optical connector at the other end, and one or more optical fibers disposed therebetween to facilitate optical communication over much of the length of the active cable. The communication may be one direction or even duplex.

Abstract: Thermally tunable optical dispersion compensation (ODC) devices are disclosed. In one aspect, an ODC device may include multiple Gires-Tournois (G-T) etalons. The etalons may be optically coupled together. The etalons may compensate for optical dispersion by collectively delaying light. At least one of the G-T etalons may have a temperature dependent partial reflector. The ODC device may also include at least one thermal device to change the temperature of the G-T etalon having the temperature dependent partial reflector. Methods of making and using the ODC devices are also disclosed, as well as various systems including the ODC devices.

Abstract: Embodiments of an optical detection apparatus are disclosed which may include one or more of a waveguide, a trench formed in the waveguide, a reflective surface, and a photodetector. The waveguide may be formed in a semiconductor substrate to propagate an optical signal received at a first end of the waveguide. The trench may also be formed in the waveguide having a first sidewall and a second sidewall, the first and second sidewalls forming first and second angles with the waveguide's propagation direction. The second sidewall may include a reflective surface formed thereon. The photodetector may be configured to receive an optical signal propagated in the waveguide, through the first sidewall and reflected from the reflective surface on the second sidewall.

Abstract: In one embodiment, an assembly having a first board, a second board, a fiber bundle, and at least one movable stage is provided. The fiber bundle has a first end and a second end, and the first end of the fiber bundle is attached to the first board first face. The movable stage has a second optical array provided thereon or therein. The movable stage is disposed on the second board such that the at least one motor steers the movable stage. The movable stage is steered such that the second optical array is aligned with the second end of the fiber bundle in a desired manner.

Abstract: Embodiments provide single fiber bidirectional HDCP modules. A signal fiber module includes at least one laser and at least one detector and a waveguide combiner/splitter. An optical fiber is used as a cylindrical lens in order to partially collimate in the vertical axis the optical signals entering and leaving branches of a waveguide. The branches of the waveguide have lens-shape interfaces in order to at least partially collimate in the horizontal axis the beams entering and leaving the waveguide. Each branch of the waveguide tapers toward a join-section of the waveguide. At the join section, the cross-section of a laser branch is smaller than the cross-section of a detector branch. If more than one detector is present in a module, the cross-sections of the detector branches differ from each other. If more than one laser is present in a module, the cross-sections of the laser branches differ from each other.

Abstract: An optical fiber socket includes a hollow insulative housing, two openings in a bottom face of the insulative housing for receiving two optical fiber plugs and two illuminating elements accommodated inside the insulative housing for connection with the optical fiber plugs. The insulative housing has a first baffle and a second baffle to divide the insulative housing into a first receiving space for receiving therein one illuminating element, a second receiving space for receiving therein the other illuminating element. Terminals are provided to engage with the illuminating element in the first receiving space and have elongated ends extending out of the insulative housing thereof such that two optical fiber plugs in connection to the insulative housing are able to complete information input/output.

Abstract: An optical connector system assembled from modular components. These components include connector modules that position ferrules for mating and providing fine alignment to fibers. The modules are assembled to support members to form connectors of various sizes. Mounting modules are attached to the support members. Various shaped mounting modules are provided, allowing connectors to be assembled for various configurations, such as a matrix configuration, a parallel board-to-board configuration or a panel mount configuration.

Abstract: An optical transceiver module including a housing and a plurality of optical transceiver devices is provided. The housing has a connector portion disposed at an end thereof. The connector portion includes two receptacles formed thereon. The optical transceiver devices are disposed in the housing, corresponding to the receptacles. Each one of the optical transceiver devices includes a printed circuit board, an optoelectronic component and a connecting interface. The printed circuit board is disposed substantially perpendicular to a bottom surface of the housing. The optoelectronic component has an optical fiber interface, a reception portion and a transmission portion. The orientation of the optical fiber interface, the orientation of the reception portion and the orientation of the transmission portion are parallel to the printed circuit board.

Abstract: An optical communication system (200) for transmitting light between a first housing (102) and a second housing (104) of a device (100) is provided. The first housing and the second housing are adapted to move relative to one another between a plurality of usage positions. The optical communication system includes a first optical communication element (202), a second optical communication element (204), and an optical waveguide (206). The first optical communication element is capable of emitting light and can be coupled to one of the first and second housing. The second optical communication element is capable of receiving the light and can be coupled to the housing to which the first optical communication element is not coupled. The optical waveguide is capable of conveying the light emitted by the first to the second optical communication element. The second optical communication element can substantially encompass a locus of the output light.

Abstract: An optical communication coupling system (206) for use in a device is provided. The optical communication coupling system (206) includes an optical fiber (208) and a clip connector (302). The optical fiber (208) is capable of conveying light between a first optical communication element (202) and a second optical communication element (204). The clip connector (302) is capable of receiving the optical fiber (208) and altering it to create an access point, which allows for a transfer of light between the optical fiber (208) and one of the first optical communication element (202) and the second optical communication element (204).

Abstract: One apparatus embodiment includes an optical emitter and a photodetector. At least a portion of the optical emitter extends a radial distance from a center point. The photodetector provided around at least a portion of the optical emitter and positioned outside the radial distance of the portion of the optical emitter.

Abstract: A photonic circuit board comprises a connection setting circuit, a group of electric wires for connecting the connection setting circuit and a plurality of devices, an optical I/O (input/output) device connected to the connection setting circuit and a two dimensional optical transmission medium connected to the optical I/O device and adapted to transmit optical signals. The connection setting circuit includes a circuit capable of changing the mode of connection of the group of electric wires and the optical I/O device.

Abstract: A power conversion apparatus is obtained which detects a mis-connection of optical fiber cables based on a difference in mode of feedback signals, and changes a phase sequence in an automatic manner only with the use of a logical composition of a microcomputer control section. A drive circuit 2 for driving a semiconductor device 1 includes a test signal recognition section 31 that outputs inherent feedback signals 32 in response to a test signal 30 from a microcomputer control section 3. The microcomputer control section 3 includes an optical fiber mis-connection detection section 29, 33 that detects a mis-connection state of the optical fibers 8 based on the inherent feedback signals 32.

Abstract: An optical module includes: an optical plug that supports one end of an optical fiber; a receptacle unit having an optical element and a mounting surface to be abutted against the optical plug for optically coupling the optical plug and the optical element; and a holder having a leaf spring that forces the optical plug to the mounting surface of the receptacle unit, a window section for passing the optical fiber, and a fiber support section disposed at a position near the window section for affixing the optical fiber thereto, wherein the holder is engaged with the receptacle unit to connect the receptacle unit and the optical plug in one piece.

Abstract: A method for passive alignment of adapters, enabling high-precision connection between components on a rigid or flexible substrate as part of a printed circuit board (PCB) is provided. Removable alignment structures are positioned in an alignment area on a PCB, where the alignment structures are in accordance with a patterned layer. An adapter, having adapter mating pins or holes, respectively, and adapter alignment pins, is placed on the PCB in the alignment area such that the adapter is aligned with the alignment structures. The adapter alignment pins are inserted into holes in the alignment structures. A ferrule is fixed on the PCB in the alignment area, and the ferrule holes or pins, respectively, are aligned to mate with the adapter mating pins or holes, respectively. The adapter is removed from the alignment structures, and finally the alignment structures are removed.

Abstract: An integrated packaging system that comprises an integral mechanical support, a printed circuit board and the optical communications device. The mechanical support includes a first support element and a second support element. The first support element extends at a non-zero angle from the second support element. The printed circuit board includes a first portion and a second portion in contact with the first support element and the second support element, respectively. The optical communications device is mechanically coupled to the first support element of the mechanical support and is electrically connected to the first portion of the printed circuit board. The integrated packaging system preferably provides automatic alignment between the optical communications device and one or both of an optical element and an optical fiber. In this case, the first support element includes a device alignment feature.

Abstract: The invention relates to a connector arrangement for optical wave guides for establishing multimedia connections in motor vehicles, e.g. in accordance with the MOST®-Standard wherein a first and a second fiber section are each enclosed by a sleeve and by connecting it fixedly with the sleeve, both sleeves form an integrally constructed, common fiber holder for the two fiber sections, which can be inserted into the rear fiber receptable of the connector housing.

Abstract: An optical transmitter for converting and coupling an information-containing electrical signal with an optical fiber having an electrical input for coupling with an external electrical cable or information system device having a plurality of parallel data lines, a modulator for converting between an information-containing electrical signal on each data line and a multi-level digital pulse amplitude modulated signal corresponding to the binary electrical signal; and a signal timing circuit coupled to said modulator for aligning the data signal to a predetermined clock signal. The transmitter is preferably wavelength division multiplexed, using an electro-optical subassembly coupled to each respective timer circuit for converting between the information-containing electrical signal and a modulated optical signal corresponding to the electrical signal at a predetermined wavelength. The transceiver is preferably implemented in a pluggable standardized form factor.

Abstract: Optically-coupled memory systems are disclosed. In one embodiment, a system memory includes a carrier substrate, and a controller attached to the carrier substrate and operable to transmit and receive optical signals, and first and second memory modules. The module substrate of the first memory module has an aperture formed therein, the aperture being operable to provide an optical path for optical signals between the controller and an optical transmitter/receiver unit of the second memory module. Thus, the system memory provides the advantages of “free space” optical connection in a compact arrangement of memory modules. In an alternate embodiment, the first memory module includes a beam splitter attached to the module substrate proximate the aperture. In another embodiment, the first and second memory modules are staged on the carrier substrate to provide an unobstructed path for optical signals.

Abstract: The invention provides a fiber plate formed by arranging in mutually adjacent manner plural individual fiber plates of a same thickness so as to provide a light guiding plane larger in area than the light guiding plane of the individual one fiber plate, and a radiation image pickup apparatus utilizing such fiber plate, in which: each of the plural individual fiber plates is composed of a group of optical fibers having mutually parallel axes, and lateral faces of the plural individual fiber plates are mutually so bonded that the axes of the optical fibers thereof become mutually parallel.

Abstract: A pluggable optical transceiver is disclosed in which, even an irregular operation is carried out, the engagement between the transceiver and the rail may be secured. The optical transceiver, which is pluggable with the rail provided in the host system, includes a grip assembled with the receptacle, a latch lever to be engaged with the rail, a leaf spring that pushes the latch lever outward and an actuator to make a seesaw motion to rotate the latch lever synchronizing with the slide of the grip. Because the center of the rotation center of the latch lever positions inward with respect to the end of the latch lever, the engagement of the latch lever with the rail may be further secured even the irregular operating is applied in the latch lever.

Abstract: An optical element and an optical transmission member are fixedly secured onto a substrate so as to be coupled to each other. In this substrate, a through hole is formed between an optical element secured portion and an optical transmission member secured portion. In an attempt to assemble these optical transmission member and optical element so as to make the coupling at an optimal position, first, the position of the optical transmission member is adjusted to an optimal position, and after measuring the position by a laser micrometer, the optical transmission member is fixedly secured thereto by using a soldering material. Thus, measurements are again carried out by the laser micrometer to detect an amount of deviation from the measured value before the securing process, and the secured portion is again fused so that the optical transmission member is shifted based on the amount of deviation, and again fixedly secured thereon.

Abstract: Disclosed are reconfigurable optical interconnections for opto-electronic processors in general, and for scalable computer architectures and scalable network servers in particular. The optical-signal interconnects are adaptable, or reconfigurable, during the normal operation of the processor. A large number of optical-signal interconnects may be provided among the components of the processor while using a small number of light transmitters and/or light receivers.

Abstract: A multilayer optical fiber coupler for coupling optical radiation between an optical device and an optical fiber, including a first layer that has a fiber socket formed by photolithographic masking and etching to extend through said first layer, and a second layer bonded to the first layer. The first layer may comprise substantially single-crystal silicon. An optical fiber is inserted into the fiber socket to align the optical fiber precisely within the fiber socket. In one embodiment the optical fiber is a single mode fiber, and an optical focusing element formed on the second layer is aligned with the core of the single mode fiber. The second layer may comprise glass having an index of refraction that approximately matches the index of the optical fiber, and an optical epoxy is used to affix the optical fiber into the fiber socket and fill the gaps between the end face of the fiber and the second layer.