Abstract: A method for adaptively fabricating a waveguide comprises: measuring misplacement of a photonic device relative to a substrate; generating computer readable instructions for using a plurality of graphics primitives to form the waveguide; and photocomposing the waveguide on the substrate in accordance with the computer readable instructions. A reticle comprises a plurality of graphics primitives with at least one of the plurality of graphics primitives comprising a tapered end. A waveguide comprises a plurality of waveguide segments with each of the plurality of waveguide segments comprising a tapered end and being adjacent to at least one other of the plurality of waveguide segments.

Abstract: A method for optical coupling comprises: includes providing a holographic recording media fixed relative to at least two optical elements; creating a hologram by transmitting light from each of the optical elements to the recording media; and transmitting light from a sending element of the optical elements through the recording media to a receiving element of the optical elements. Other variations include a system comprising at least two optical elements situated on one side of the recording media and an optical detector situated on an opposite side for detecting light transmitted through the opposite side; and a system comprising at least three optical elements situated on one side of the recording media, a beam splitter, and optical pump/control beams configured for transmitting an optical pump/control beam to the beam splitter and the opposite side so as to control transmission of an optical signal.

Abstract: A power harvesting module comprises at least one electromagnetic (EM) radiation intensity modulator configured to receive a first EM radiation from at least one source and at least one energy converter configured to at least partially convert the energy of the first EM radiation during modulation into electrical energy.

Abstract: A method and system for increasing the coupling efficiency of optical interconnections between optical elements such as optical fibers, waveguides, and vertical cavity surface emitting lasers (VCSEL) in single mode or multimode.

Abstract: The invention provides novel “folded” Mach-Zehnder interferometers (“folded” MZI's), methods for making folded MZI's, and systems and devices incorporating them. The novel folded MZI's are elaborated from conventional MZI structures by cutting across the interferometer arms of a conventional MZI structure and creating reflectors on the exposed ends of the interferometer arms to form two “folded” MZI's from a single conventional Mach-Zehnder interferometer structure. The novel folded MZI's show promise as sensors having a reduced size and enhanced sensitivity relative to sensors incorporating conventional Mach-Zehnder Interferometers.

Abstract: Embodiments of methods, apparatuses, devices, and/or systems for optical are disclosed.

Abstract: A method for adaptively fabricating a waveguide comprises: measuring misplacement of a photonic device relative to a substrate; generating computer readable instructions for using a plurality of graphics primitives to form the waveguide; and photocomposing the waveguide on the substrate in accordance with the computer readable instructions. A reticle comprises a plurality of graphics primitives with at least one of the plurality of graphics primitives comprising a tapered end. A waveguide comprises a plurality of waveguide segments with each of the plurality of waveguide segments comprising a tapered end and being adjacent to at least one other of the plurality of waveguide segments.

Abstract: An electromagnetic coupler comprising: a coupling waveguide adapted for receiving input modes along an input axis, propagating coupling modes along a coupling axis, and transmitting output modes along an output axis, the output axis being not parallel to the coupling axis; and an output waveguide disposed adjacent the coupling waveguide and adapted for receiving the output modes.

Abstract: A method for adaptively fabricating a waveguide comprises: measuring misplacement of a photonic device relative to a substrate; generating computer readable instructions for using a plurality of graphics primitives to form the waveguide; and photocomposing the waveguide on the substrate in accordance with the computer readable instructions. A reticle comprises a plurality of graphics primitives with at least one of the plurality of graphics primitives comprising a tapered end. A waveguide comprises a plurality of waveguide segments with each of the plurality of waveguide segments comprising a tapered end and being adjacent to at least one other of the plurality of waveguide segments.

Abstract: An imaging system for generating an image of an object is provided. The imaging system comprises an X-ray source disposed in a spatial relationship to the object configured to transmit X-ray radiation through the object. The system further comprises at least one X-ray detecting media configured to convert the X-ray radiation transmitted through the object to optical signals. In addition, the system comprises an optical transmission conduit comprising a first end and a second end and an optical detector configured to convert optical signals to corresponding electrical signals. The first end of the optical transmission conduit is coupled to the X-ray detection device and the second end coupled to the optical detector.

Abstract: An ultrasound system includes an ultrasound probe configured for sensing and transmitting ultrasound signals. The ultrasound system further includes an optical conduit configured for coupling a light source and an optical detector in an optical path. The optical conduit includes electro-optic modulators configured for modulating optical signals on the optical conduit with at least one of the electrical signals configured to generate corresponding optically modulated analog signals on the optical conduit. In one example, the electro-optic modulators comprise electro-optic polymer modulators.

Abstract: A method of forming a waveguide including a core region, a cladding region, and an index contrast region situated therebetween includes depositing a polymerizable composite on a substrate to form a layer, patterning the layer to define an exposed area and an unexposed area of the layer, irradiating the exposed area of the layer, and volatilizing the uncured monomer to form the waveguide, wherein the polymerizable composite includes a polymer binder and sufficient quantities of an uncured monomer to diffuse into the exposed area of the layer and form the index contrast region. The resulting waveguide includes an index contrast region which has a lower index of refraction than that of the core and cladding regions.

Abstract: A method of forming a waveguide including a core region, a cladding region, and an index contrast region situated therebetween includes depositing a polymerizable composite on a substrate to form a layer, patterning the layer to define an exposed area and an unexposed area of the layer, irradiating the exposed area of the layer, and volatilizing the uncured monomer to form the waveguide, wherein the polymerizable composite includes a polymer binder and sufficient quantities of an uncured monomer to diffuse into the exposed area of the layer and form the index contrast region. The resulting waveguide includes an index contrast region which has a lower index of refraction than that of the core and cladding regions.

Abstract: An electromagnetic coupler comprising: a coupling waveguide adapted for receiving input modes along an input axis, propagating coupling modes along a coupling axis, and transmitting output modes along an output axis, the output axis being not parallel to the coupling axis; and an output waveguide disposed adjacent the coupling waveguide and adapted for receiving the output modes.

Abstract: A method for optical coupling comprises: providing a holographic recording media fixed relative to at least two optical elements; creating a hologram by transmitting light from each of the optical elements to the recording media; and transmitting light from a sending element of the optical elements through the recording media to a receiving element of the optical elements. Other variations include a system comprising at least two optical elements situated on one side of the recording media and an optical detector situated on an opposite side for detecting light transmitted through the opposite side; and a system comprising at least three optical elements situated on one side of the recording media, a beam splitter, and optical pump/control beams configured for transmitting an optical pump/control beam to the beam splitter and the opposite side so as to control transmission of an optical signal.

Abstract: A technique for implementing a tunable micro-ring filter is disclosed. According to an embodiment of the present invention, a tunable filter for optical communication systems comprises a first waveguide forming a pattern with a second waveguide; a resonator coupled to the first waveguide and the second waveguide wherein the resonator comprises a nonlinear optical material; an electrode structure sandwiching the first waveguide, the second waveguide and the resonator; the electrode structure adapted for receiving a tuning signal and tuning an effective index of the resonator in response to the tuning signal; and a substrate supporting the first waveguide, the second waveguide, the resonator and the electrode structure.

Abstract: A method and system for increasing the coupling efficiency of optical interconnections between optical elements such as optical fibers, waveguides, and vertical cavity surface emitting lasers (VCSEL) in single mode or multimode.

Abstract: An optical device structure comprising a substrate and at least one topological feature. The topological feature comprises a polymeric composite material formed from a polymerizable binder and an uncured monomer. The topological feature has a controlled topological profile and a controlled refractive index across the topological feature. The optical device structure may be a multimode waveguide device, a single mode waveguide device, an optical data storage device, thermo-optic switches, or microelectronic mechanical system.

Abstract: Embodiments of the present invention are directed to a method of processing an optical fiber to match the optical field coming out of the fiber to that accepted into the optical waveguide to reduce the optical losses due to the optical mode mismatch of the interconnection. In one embodiment, a method of tapering an end of an optical fiber comprises providing a flow of etch vapor from an etch solution generally in an etch vapor flow direction, a concentration of the etch vapor decreasing with distance in the etch vapor flow direction; providing an optical fiber have an end portion with a tip, the end portion of the optical fiber including a core and a clad; and subjecting the end portion of the optical fiber to the flow of etch vapor from the etch solution to etch the end portion and form a taper at the end portion. The end portion is disposed generally along the etch vapor flow direction and the tip of the end portion points generally in a direction opposite from the etch vapor flow direction.

Abstract: A method for adaptively fabricating a waveguide comprises: measuring misplacement of a photonic device relative to a substrate; generating computer readable instructions for using a plurality of graphics primitives to form the waveguide; and photocomposing the waveguide on the substrate in accordance with the computer readable instructions. A reticle comprises a plurality of graphics primitives with at least one of the plurality of graphics primitives comprising a tapered end. A waveguide comprises a plurality of waveguide segments with each of the plurality of waveguide segments comprising a tapered end and being adjacent to at least one other of the plurality of waveguide segments.