Abstract: In one embodiment, a fiber assembly is provided. The fiber assembly has a first fiber having at least one core. The core has a length, a first end, and a second end, and light may be transmitted along the core. The second end has an obtusely angled end surface. The assembly also has a second fiber having at least one core having a first end. Light may be transmitted along the core. The second end of the first fiber is optically coupled to the first end of the second fiber such that light emitted from the first fiber may be transmitted to the second fiber.

Abstract: In one embodiment, a system comprises a plurality of electronic circuit boards and at least one optical fiber in optical communication with at least one circuit board of the plurality of electronic circuit boards, wherein at least one optical fiber comprises at least one core having at least one end surface, and wherein at least one end surface comprises a light dispersing geometry.

Abstract: A controllable optical ring resonator, a photonic system and a method of controlling an optical ring resonator employ control electrodes periodically spaced apart along a closed loop optical path of an optical waveguide. The controllable optical ring resonator includes the optical waveguide and a plurality of the periodically spaced control electrodes. The photonic system includes an input optical waveguide segment and the controllable optical ring resonator adjacent and optically coupled to the segment. The method includes providing the plurality of periodically spaced control electrodes, providing an optical signal within the optical path, and addressing one or more of the control electrodes to interact with the optical signal within the optical path.

Abstract: In one embodiment, method of forming fibers is provided. The method includes modifying a first exposed edge of at least one core of a first fiber. The first fiber has a first end, a second end, and a length between the first end and the second end. The second end has the first exposed edge of the core, and the first exposed edge has a first diffusion state. The first fiber may transmit light along the core. The modification of the first exposed edge includes modifying the first diffusion state of the first exposed edge of the core to a second diffusion state such that light exiting the first exposed edge in the second diffusion state is spread over a greater number of angles relative to angles of the light exiting the first exposed edge in the first diffusion state.

Abstract: A method of aligning optical data communication channels between system functions comprises: emitting an array of light beams from a corresponding array of data emitters in response to electrical data signals generated from a first system function; emitting light beams from two control emitters in response to electrical control signals generated from the first system function; receiving light beams from the data emitters by a corresponding array of data detectors to form an array of data optical communication channels; conducting electrical data signals reproduced from the received data emitter light beams to a second system function; receiving light beams from the two control emitters by two control detector sections to form two control optical communication channels; conducting electrical control signals reproduced from the received control emitter light beams to a second system function; monitoring a multiplicity of light detectors of each of the two control detector sections to determine an offset in opti

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: 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: In one embodiment, method of forming fibers is provided. The method includes modifying a first exposed edge of at least one core of a first fiber. The first fiber has a first end, a second end, and a length between the first end and the second end. The second end has the first exposed edge of the core, and the first exposed edge has a first diffusion state. The first fiber may transmit light along the core. The modification of the first exposed edge includes modifying the first diffusion state of the first exposed edge of the core to a second diffusion state such that light exiting the first exposed edge in the second diffusion state is spread over a greater number of angles relative to angles of the light exiting the first exposed edge in the first diffusion state.

Abstract: An array of light beam emitter sections comprises: a substrate having a surface divided into an array of sections; and a grouping of light emitters disposed at each surface section and configured to emit light beams at different emission angles with respect to the surface. Also disclosed is apparatus for establishing optical communication channels between the array of light beam emitter sections and an array of light detectors. Further disclosed is a method of establishing optical communication channels between the array of light emitter sections and the array of light detectors by mapping at least one light emitter of each grouping with a light detector of the detector array to establish optical communication channels between the arrays based on the mappings.

Abstract: An array of light beam emitter sections comprises: a substrate having a surface divided into an array of sections; and a grouping of light emitters disposed at each surface section and configured to emit light beams at different emission angles with respect to the surface. Also disclosed is apparatus for establishing optical communication channels between the array of light beam emitter sections and an array of light detectors. The apparatus comprises a controller coupled to the arrays of emitter sections and detectors for mapping at least one light emitter of each grouping with a light detector of the detector array to establish optical communication channels between the arrays based on the mappings.

Abstract: A system for self-configuring optical communication channels between arrays of emitters and detectors comprises: an array of light emitters; an array of light detectors roughly aligned with the array of light emitters; and self-configuration logic for controlling the light emitters of the emitter array to transmit optical data to the array of light detectors and for monitoring received optical data of the light detectors of the detector array to establish light emitter/detector optical channels between the arrays of light emitters and light detectors based on optical data transmission error rates.

Abstract: A system for configuring fiber optic communication channels between arrays of emitters and detectors comprises: an array of light emitters; an array of light detectors; a bundle of optical fibers disposed between the arrays of light emitters and light detectors for conducting light from the light emitters to the light detectors, wherein the number of optical fibers in the bundle is greater than the number of light emitters in the array and wherein an area cross-section of the bundle of optical fibers overlaps the array of light emitters and the array of light detectors; and logic for mapping at least one emitter to at least one detector to establish at least one optical fiber communication channel between the array of light emitters and the array of light detectors. The system is further operative to monitor data communication over the at least one fiber optic communication channel and to reconfigure the mapping based on the monitored data communications thereof.

Abstract: A power module includes a plurality of converters having outputs for coupling to a supply voltage. The power module further includes a connector having a pin to provide a signal indicative of whether the power module is being disconnected from a system. A controller is responsive to the signal indicating that the power module is being disconnected by sequentially deasserting enable signals to the converters to disable the converters in a sequential order.

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: In at least some embodiments, a multi-processor power module comprises components that are replicated at least for each of the plurality of processors. The multi-processor power module further comprises control logic that is configured to detect a demand from each of the plurality of processors and to direct the replicated components to provide a regulated power based on the demand, the regulated power being output for sharing among the plurality of processors.

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: In one embodiment, a fiber assembly is provided. The fiber assembly has a first fiber having at least one core. The core has a length, a first end, and a second end, and light may be transmitted along the core. The second end has an obtusely angled end surface. The assembly also has a second fiber having at least one core having a first end. Light may be transmitted along the core. The second end of the first fiber is optically coupled to the first end of the second fiber such that light emitted from the first fiber may be transmitted to the second fiber.

Abstract: In one embodiment, a fiber assembly is provided. The fiber assembly has a first fiber having at least one core. The core has a length, a first end, and a second end, and light may be transmitted along the core. The second end has an obtusely angled end surface. The assembly also has a second fiber having at least one core having a first end. Light may be transmitted along the core. The second end of the first fiber is optically coupled to the first end of the second fiber such that light emitted from the first fiber may be transmitted to the second fiber.

Abstract: Various embodiments of a fiber optic module adapted for use in an electronic assembly and system are provided. Multiple embodiments of a method of interfacing an electronic assembly with an external circuit through use of the fiber optic module are also provided. In one embodiment, the fiber optic module includes a mounting bracket, a fiber optic connector, and an electrical cable connection. In one embodiment, the method includes: a) providing an electronic assembly comprising a bulkhead panel, a backplane, a fiber optic module, and an electrical cable, b) providing a fiber optic cable associated with the external circuit, and c) removably connecting the fiber optic cable a fiber optic connector of the fiber optic module at the front of the bulkhead panel.

Abstract: A system for configuring fiber optic communication channels between arrays of emitters and detectors comprises: an array of light emitters; an array of light detectors; a bundle of optical fibers disposed between the arrays of light emitters and light detectors for conducting light from the light emitters to the light detectors, wherein a diameter of each optical fiber in the bundle is greater than a diameter of light emitted from each light emitter in the array, and wherein an area cross-section of the bundle of optical fibers overlaps the array of light emitters and the array of light detectors; and logic for mapping at least one emitter to at least one detector to establish at least one fiber optic communication channel between the array of light emitters and the array of light detectors. A counterpart method is also disclosed.