Abstract: An end-face lapping apparatus, comprises a rod member W supported on an apparatus main body by a support mechanism through a fixing jig board. A lapping board has a lapping member for lapping the rod member and is rotatably swingably supported on the apparatus main body by a drive mechanism. The drive mechanism causes the lapping board to rotate about a first rotating center and at the same time swivel rotating center about a second rotating center to thereby carry out lapping while urging the rod member W fitted in the fixing jig board against the lapping member of the rotatably swinging lapping board by the support mechanism. The end-face lapping apparatus has a relative position shift device for shifting the relative position of the lapping board and the fixing jig board. The rod member W is lapped at a different portion of the lapping member each time the relative position shift device shifts the relative position of the lapping board.

Abstract: Disclosed is a hybrid waveguide structure, wherein a core or cladding has a hybrid section or “button” of a different optical property such as refractive index from the major portion of the core or cladding, respectively. The hybrid section can be made of a passive material or an electro-optic material. Methods of making a hybrid waveguide structure are also disclosed. These methods include rib-based methods and trench-based methods, and in either of these methods, a temporary filler is used in many instances to incorporate the hybrid section into the hybrid waveguide structure.

Abstract: A system and method for polishing an optical fiber with a polishing lap. The system comprises a substrate, an optical fiber disposed on the substrate so as to be outwardly curved, and an electrical conductor disposed over the outward curve of the optical fiber. A voltage source is connected to the electrical conductor, and the polishing lap is configured to initially abrade the electrical conductor to cause severance thereof. The position of the polishing lap when the electrical conductor is severed represents a reference point approximately indicating the surface of the optical fiber. A detector connected to the electrical conductor detects a change in voltage therein, indicating severance of the electrical conductor, and subsequently monitors the polishing depth relative to the reference point.

Abstract: An information recording/reproduction apparatus including a near field optical head having a minute aperture formed thereon, a substantially rod-like optical waveguide having a core and a clad, a reflection surface formed on one of end faces of the optical waveguide, for irradiating light to the near field optical head, a light reception portion and a recording medium, and utilizing near field light, a lens function is formed on a surface of the near field optical head different from the surface of the minute aperture, and a core end face is formed at an intermediate part of the optical waveguide.

Abstract: An optical resonator system includes a substrate, and a SPARROW optical waveguide disposed on the substrate for evanescently coupling light into an optical microcavity. The SPARROW waveguide includes a multi-layer dielectric stack formed of alternating high and low refractive index dielectric layers, and a waveguide core disposed on the dielectric stack. The waveguide core has an input end and an output end, and is adapted for transmitting optical radiation incident on the input end to the output end. The optical microcavity is disposed at a distance from the optical waveguide that is sufficiently small so as to allow evanescent coupling of light from the optical waveguide into the optical microcavity. The dielectric stack in the SPARROW waveguide isolates the waveguide core and the microcavity from the substrate, so that an optical coupling efficiency approaching 100% can be obtained.

Abstract: A micro-opto-electro-mechanical systems (MOEMS) modulator based on the phenomenon of frustrated total internal reflection (FTIR). The modulator effects amplitude and phase modulation at the boundary of a waveguide. Wavelength-specific switching is achieved by spatially separating the wavelength channels by dispersing a broadband input signal into its wavelength components through a grating. In exemplary embodiments, an array of micro-fabricated actuators is used to switch or modulate wavelengths individually. Applications include wavelength and space-resolved phase and amplitude modulation of optical beams, and re-configurable add/drop switching of dense wavelength-division multiplexed (DWDM) optical communication signals.

Abstract: The invention relates to an optical multiplexer/demultiplexer able to combine and/or separate at least two optical signals amongst n propagating at different wavelengths, characterised in that it comprises at least one central waveguide (4) and two lateral waveguides (5, 6), each lateral waveguide (5 and 6) constituting with the central guide (4) a pair of waveguides, each pair being disposed so as to allow a bidirectional evanescent coupling of an associated wavelength between the guides in each pair (4, 5) and (4, 6), the coupling being selective with respect to wavelength and assisted by at least one etched grating (&Lgr;), the said waveguides (4, 5, 6) being designed so that the multiplexer/demultiplexer has a functioning independent of the state of polarisation of the signals. The present invention applies to optical filters and/or direct-access networks for a bidirectional communication in the 1.3 ± &mgr;m window simultaneously with a video distribution at 1.5 &mgr;m.

Abstract: Disclosed is a hybrid waveguide structure, wherein a core or cladding has a hybrid section or “button” of a different optical property such as refractive index from the major portion of the core or cladding, respectively. The hybrid section can be made of a passive material or an electro-optic material. Methods of making a hybrid waveguide structure are also disclosed. These methods include rib-based methods and trench-based methods, and in either of these methods, a temporary filler is used in many instances to incorporate the hybrid section into the hybrid waveguide structure.

Abstract: The present invention provides a photonic local oscillator signal generator. The generator includes a plurality of waveguides fabricated in a single substrate. The waveguides are fabricated with a lateral separation that enables an evanescent tail of an optical mode field generated in one waveguide to overlap with an evanescent tail of an optical mode field generated in an adjacent waveguide. The overlap of the evanescent tails produce cross-coupling between the laser light generated in the adjacent waveguides. The generator uses a common pumping element to pump laser cavities of both of the waveguides. The use of a common pumping element and the cross-coupling produces phase locking between the laser light generated in the plurality of waveguides. As a result of the phase locking, mutual optical coherence between the laser light is achieved. The mutual optical coherence provides an interference signal upon photodetection.

Abstract: Disclosed is a hybrid waveguide structure, wherein a core or cladding has a hybrid section or “button” of a different optical property such as refractive index from the major portion of the core or cladding, respectively. The hybrid section can be made of a passive material or an electro-optic material. Methods of making a hybrid waveguide structure are also disclosed. These methods include rib-based methods and trench-based methods, and in either of these methods, a temporary filler is used in many instances to incorporate the hybrid section into the hybrid waveguide structure.

Abstract: A waveguide coupler comprises at least a first waveguide coupled at a coupling region to a second waveguide such that at least a part of radiation propagating along the first waveguide is coupled into the second waveguide. The second waveguide comprises a diffraction grating disposed at the coupling region to inhibit coupling of radiation from the first waveguide into the second waveguide at wavelengths characteristic of the diffraction grating.

Abstract: A laser-diode assembly for generating a frequency-stabilized narrow-bandwidth light comprises a light source in the form of a semiconductor laser diode coupled via a first optical coupling device to one end of a first optical fiber. The other end of this fiber is coupled to a second or an output fiber via a second optical coupling device. The assembly is characterized by the fact that a long inner cavity is formed by a section of the optical system between two oppositely directed mirrors. The first mirror is applied onto the back side of the semiconductor laser diode, and the second mirror is applied onto a flat front side of one optical lens element or onto the back side of another optical lens element. These optical lens elements are parts of an optical coupling between the first and the second fibers. The first mirror completely reflects the entire light incident onto this mirror, whereas the second mirror reflects a major part of the light, e.g., about 90% and passes only a small part, e.g.

Abstract: Techniques for coupling optical energy between a side-polished port of a fiber in one substrate and a coupling port of a waveguide in another substrate.

Abstract: A near-field optical probe comprises a micro-aperture for irradiating and/or detecting evanescent light through the front end of the probe, an elastically deformable cantilever supporting the micro-aperture at the free end thereof, and a surface plasmon polariton waveguide arranged on the cantilever to guide light from a light source to the micro-aperture and/or to guide light from a light source introduced through the micro-aperture.

Abstract: Tunable add-drop and cross connect devices include materials with negative refractive index dependence on temperature and temperature independent coincidence between modes of an athermal ring resonator and a set of specified frequencies, e.g. for DWDM telecommunications channels. The free spectral range may be adjusted to equal a rational fraction of the specified frequency interval. The operating frequency may be selected without substantially tuning the resonator modes by a thermo-optically tuned feedback element having a waveguide pair with differential thermal response. The operating frequency may be induced to hop digitally between the specified frequencies.

Abstract: An asymmetric waveguide pair (1440) with a differential thermal response has an optical coupling frequency that may be thermo-optically tuned. Tuning may also be accomplished by applying an electric field (1445) across a liquid crystal portion (1442) of the waveguide structure. The waveguide pair may include a grating and be used as a frequency selective coupler for an optical resonator. The differential waveguide pair may also be used as a temperature or electric field sensor, or it may be used in a waveguide array to adjust a phase relationship, e.g. in an arrayed waveguide grating.

Abstract: A system of coupling optical energy in a waveguide mode, into a resonator that operates in a whispering gallery mode. A first part of the operation uses a fiber in its waveguide mode to couple information into a resonator e.g. a microsphere. The fiber is cleaved at an angle &PHgr; which causes total internal reflection within the fiber. The energy in the fiber then forms an evanescent field and a microsphere is placed in the area of the evanescent field. If the microsphere resonance is resonant with energy in the fiber, then the information in the fiber is effectively transferred to the microsphere.

Abstract: Optical Mach-Zehnder interferometers and related devices, systems that have at least one fiber integrated or engaged to a substrate fabricated with one or more grooves.

Abstract: A resonant optical filter including a first and second transmission optical waveguides, and a resonator, which resonator may include one or more resonator segements evanescently optically coupled therebetween. The resonator supports a circumferential resonant optical mode and is evanescently coupled to each of the first and second transmission optical waveguides.

Abstract: A method and apparatus for polishing the side surfaces of fiber optics destined for devices in which the evanescent optical field of the optics must be accessed through polished side surfaces thereof. A plurality of fiber optics are temporarily affixed to a rounded surface, for polishing of the outer-facing surfaces thereof. In one embodiment, fiber optics are positioned across a cylindrical lens, perpendicular to a longitudinal axis thereof, and are temporarily affixed thereto using a wax. Polishing commences, which can be monitored for progress using visual or optical power measurements. The fiber optics are thereafter removed from the lens, ready for installation into their respective devices.

Abstract: A method for fabricating an optical resonator on an optical fiber including the steps of generating a differential of a physical property (e.g., diameter, density, refractive index, chemical composition, and so forth) of a transverse segment of the resonator fiber. The resonator fiber segment may substantially confine a circumferential optical mode propagating around the resonator fiber segment circumference at least partially within the resonator fiber segment, thereby enabling substantial confinement of a substantially resonant circumferential optical mode near a surface of the fiber, and enabling evanescent optical coupling between circumferential optical mode and an optical mode supported by a second optical element. Specialized techniques for spatially selectively generating the differential may include masking/etching, masking/deposition, laser machining, laser patterning, combinations thereof, and/or functional equivalents thereof.

Abstract: Controllable fiber optic attenuators and attenuation systems (100) are disclosed for controllably extracting optical energy from a fiber optic (30), and therefore attenuating the optical signal being transmitted through the fiber optic (30). In one aspect, material is removed from a portion of the optical fiber (30), thereby exposing a surface through which optical energy can be extracted. A controllable material is formed over the surface for controllably extracting optical energy according to a changeable stimulus applied thereto, which affects the refractive index thereof. In an improved embodiment, a controllable material is formed over the exposed surface for controlling the amount of optical energy extracted from the fiber optic, and a bulk material is formed over the controllable material, into which the extracted optical energy is radiated.

Abstract: An optical amplifier includes first and second optical fibers. The first optical fiber has a core, a first cladding surrounding the core and a second cladding surrounding the first cladding. The second optical fiber has an end physically coupled to a side portion of the first optical fiber. The end transmits light to the first cladding.

Abstract: A micromechanical optical switch structure, that may be integrated to form an array of optical switches, switches light between a main waveguide and a switched waveguide. The switched waveguide has a coupling portion and two flexible portions and is coupled to a movable cantilever arm. The cantilever arm is configured to move at least the coupling portion of the switched waveguide between first and second positions with respect to the main waveguide. In the first position, the switched waveguide is evanescently coupled to the main waveguide and in the second position, the switched waveguide is not evanescently coupled to the main waveguide. The movable cantilever arm may be formed with bimaterial arms that move the switched waveguide in response to heat or a piezoelectric potential being applied to the arm or they may be formed with an electrostatic plate that moves the arms in response to an electrostatic potential.

Abstract: The present invention applies to resonant optical power control device assemblies and methods relating thereto, and includes an alignment device preferably including one or more waveguide-alignment grooves, resonator alignment grooves, and alignment groves for a second optical element including a modulator. One embodiment includes a transmission optical waveguide, a circumferential-mode optical resonator; and a second optical element, optionally including one or more of an optical modulator or a second transmission optical waveguide, and optionally including a modulator optical control element. In this embodiment, the alignment grooves reliably establish and stably maintain evanescent optical coupling between the optical elements positioned in such grooves. A method for assembling a resonant optical power control devices is also disclosed.

Abstract: A wavelength-selective optical device for coupling of light at predetermined wavelength from one optical fiber waveguide to another using at least two gratings and cladding-mode assisted coupling is disclosed. The transfer of light is performed using intermediate coupling to one or more cladding mode of the waveguides. In the case when the fibers have physically different claddings, an arrangement for transfer of light from one cladding to another is required. The disclosed coupler has no back-reflection, small insertion loss, and very high channel isolation. The device can be used in wavelength-division multiplexing networks.

Abstract: The invention relates to an all-fiber add/drop filter. A wide-band light is input one port of a photosensitive fiber and affected by a Bragg grating, and then deviated a Bragg wavelength and a transmission light satisfying the Bragg condition. The Bragg wavelength and transmission light couple from one fiber to the other, wherein the Bragg wavelength is dropped at one port of another optical fiber and the transmission light is added to another port of another optical fiber.

Abstract: Techniques and devices for integrating optical fibers on substrates with grooves for various optical applications. Two openings that penetrate through the substrate are formed at both ends of each groove to allow a fiber to pass from one side of substrate to another side. The fiber cladding of a fiber portion positioned in the groove can be removed to produce an optical coupling port.

Abstract: A photonic integrated circuit (PIC) device comprising two or more vertically stacked asymmetric waveguides is provided. A photo-detector PIC device comprises a coupling waveguide for providing low-coupling loss with an external optical fiber and for guiding primarily a first mode of light, a second waveguide vertically coupled to the first waveguide for guiding primarily a second mode of light having an effective index of refraction different from the first mode, and a photo-detector vertically coupled to the second waveguide. Light received at the coupling waveguide is moved into the second waveguide via a lateral taper in the second waveguide. The photo-detector PIC device may further comprise a third waveguide having an optical amplifier therein and positioned between the coupling waveguide and the second waveguide.

Abstract: An optical device which has: a first optical waveguide disposed on a substrate having a thermo-optical effect; a second optical waveguide that, at its one end, has part which is disposed close to and in parallel with part of the first optical waveguide by a predetermined length on the substrate, and that, at the parallel part, is evanescent-coupled with light propagating through the first optical waveguide; light reflector that is disposed opposed to the end faces, at the one end, of the first and second optical waveguides and that totally reflects light emitted from the end faces; and distribution ratio altering system that heats around the evanescent-coupled parallel part of the first and second optical waveguides to alter a distribution ratio of lights emitted from the other ends of the first and second optical waveguides to which incident light supplied to the first optical waveguide at the other end is distributed.

Abstract: A tapered optical fiber coupler includes a first fiber with a core (11) and a cladding (12) and a second fiber with a core (21), an inner cladding (22) and an outer cladding (23). In the stretched, coupling regions of the device, the coupling regions (44, 50) of the fibers form of coupling region waveguides with dispersion curves crossing one another at a preselected operating wavelength. The one or more claddings of each fiber has a monotonic decreasing refractive index distribution, and the refractive index distributions of the claddings (12, 22, 23) are different from one another. Coupling of light from one another occurs only in the narrow band of wavelengths surrounding the operating wavelengths. The outside diameters and core diameters of the fibers may be identical to one another and identical to those of standard optical fibers. Thus, the device can be connected in an optical system.

Abstract: The present invention relates to an electrooptic method of signal processing, characterized in that it comprises the steps consisting in: providing at least one semiconductor component consisting at least of a substrate (10) and of a superposed assembly comprising at least one guiding layer (14) and applying, to the guiding layer (14), optical radiation at a wavelength and at an angle of incidence chosen in such a way that said assembly has, at this wavelength and at this angle of incidence, a specific absorption peak suitable for allowing said optical radiation to be guided in the guiding layer (14) The invention also relates to a device for implementing this method, as well as the use of the latter.

Abstract: A device comprising a planar optical waveguide, consisting of a transparent carrier (40) and a wave-guiding layer (41), wherein the waveguide at least has a diffractive element (42) for coupling excitation radiation into the wave-guiding layer, and there is located on the wave-guiding layer a further, tightly sealing layer (43) made from a material which, at least at the support surface, is transparent both to the excitation radiation and to the evanescently excited radiation at least to the penetration depth of the evanescent field, and which, for an analysis sample, has, at least in a partial region of the guided excitation radiation, a cavity (45) which is open to the upper side or a cavity (6) which is closed to the upper side and connected by means of an inflow channel (2) and an outflow channel (3), the depth of the cavity corresponding at least to the penetration depth of the evanescent field, and wherein the diffractive element (42) is fully covered by the material of the layer (43) at least in the co

Abstract: A method for monitoring the interaction of molecular species utilizes a sensor device comprising a substrate (1) with a waveguide (2) formed on the surface thereof. A grating (3) is formed in one of the surfaces of the waveguide (2). A beam of light (6) is incident on the grating (3) and the angle of incidence at which maximum reflection occurs is monitored. A first molecular species is immobilized on the waveguide (2). Changes in the angular position of the reflection maximum provide an indication of interaction of the first molecular species with a second molecular species contained in a sample brought into contact with the sensor device.

Abstract: A class of opto-electronic mechanical devices that include a planar optical waveguide having a cladding in which there is carried an evanescent electric field by a light beam traveling along the waveguide and a mechanical micro-element controllably coupled into the evanescent field for varying locally the properties of the waveguide in a wavelength dependent fashion. The devices described include optical switches and WDM add/drop apparatus.

Abstract: A method of analyzing a chemical reaction in a material including the steps of embedding in a material an optical fiber having a cladding along substantially the entire length thereof that is in contact with the material, transmitting light through the optical fiber, and performing evanescent wave spectroscopy on the light transmitted through the optical fiber. The optical fiber preferably has a core 10-30 &mgr;m in diameter and a cladding that is on the order of 1 &mgr;m thick.

Abstract: A multimode waveguide device for assays includes a multimode waveguide with a patterned, reflective surface coating. The exposed portion or portions of the reflectively coated waveguide surface are for analyte recognition. A fluidics cell is attached to the waveguide so that the channel or channels of the fluidics cell match with the exposed portion or portions of the waveguide surface. The channel or channels direct one or more sample fluids over the exposed portion or portions of the waveguide surface. The reflective coating minimizes loss and scattering of excitation and fluorescence light during a fluorescence assay.

Abstract: Disclosed is a hybrid waveguide structure, wherein a core or cladding has a hybrid section or "button" of a different optical property such as refractive index from the major portion of the core or cladding, respectively. The hybrid section can be made of a passive material or an electro-optic material. Methods of making a hybrid waveguide structure are also disclosed. These methods include rib-based methods and trench-based methods, and in either of these methods, a temporary filler is used in many instances to incorporate the hybrid section into the hybrid waveguide structure.

Abstract: An N-port optical wavelength division multiplexer and demultiplexer includes two evanescent wave couplers connected by N optical paths. Each of the optical paths includes wavelength-selecting elements that are used to select specific wavelengths of light. Light signals composed of N wavelengths of light introduced to an exterior port in one of the couplers are split substantially equally among all the optical paths within the coupler, so that each optical path exiting the coupler includes light of all the wavelengths initially introduced to the coupler. The wavelength selecting elements disposed on each optical path are situated to direct the light in a manner such that light of only the selected wavelengths interferes constructively at a given exterior coupler port and other wavelengths interfere destructively. Consequently, optical signals composed of N wavelengths may be demultiplexed such that N optical paths carry light having one wavelength.

Abstract: A compact optical waveguide employs a photonic band gap element as a reflector to enable a light beam to be reflected at angles greater than the critical angle. The photonic band gap device is a two-dimensional array of columnar holes formed in the substrate the holes are filled with air or another material having a different dielectric constant than the substrate. The optical waveguide forms a right angle bend and first and second photonic band gap devices are formed on both the inside and outside angles of the bend to deflect light which is incident on the waveguide at an angle greater than a critical angle defined by the materials that constitute the optical waveguide. The columnar holes of the photonic band gap element have a diameter of approximately one-half wavelength and are arranged in a triangular packing having an inter-column separation of approximately one-half wavelength of the light which is to be transmitted through the waveguide.

Abstract: A tunable filtering device comprising a base; first and second optical fibers aligned and facing each other; a tunable filter installed on the optical path between the first and second optical fibers, for transmitting only a beam of a specific wavelength from the beam emitted from the first optical fiber toward the second optical fiber; an actuator driving the tunable filter; a beam splitter installed on the optical path between the tunable filter and the second optical fiber, for reflecting a portion of the beam transmitted through the tunable filter and transmitting the rest; an auxiliary optical fiber installed on the base, for receiving a beam reflected from the beam splitter for further transmission; and a controller detecting the beam transmitted through the auxiliary optical fiber and controlling the actuator according to the detected beam.

Abstract: The present invention is an optical switch that includes a first optic fiber waveguide, a second optic fiber waveguide, and a third optical waveguide. The three waveguides are in the same plane. The third optical waveguide may be an optic fiber or a slab waveguide. The first and second optic fiber waveguides are close enough to exhibit evanescent wave coupling under non-interference conditions. The second optic fiber waveguide is between the other two waveguides and closer to the third optical waveguide. The first and second optic fiber waveguides have identical propagation constants. An information-bearing optical signal is applied to the first optic fiber waveguide. An optical control signal applied to the third optical waveguide controls its propagation constant and, therefore, controls whether or not switching occurs between the first and second fiber optic waveguides. The optical switch may be made to be normally on or normally off.

Abstract: A method of monitoring power of laser-radiation laterally coupled from a diode-laser into an optical-fiber is disclosed. An input-end of the optical-fiber has a polished surface inclined at an angle to a longitudinal axis of the fiber. The input-end of the optical-fiber is arranged proximate an output-facet of the diode-laser such that radiation emitted from the facet is transmitted laterally into the optical-fiber and is incident internally on the polished surface. A fractionally-transmitting reflective coating is provided on the polished surface, whereby a fraction of the laser-radiation incident on the polished surface is transmitted out of the optical-fiber. A radiation-detector responsive to the laser-radiation is located in a position to receive the transmitted fraction of laser-radiation, thereby generating a signal which is interpreted as measure of power of the laser-radiation coupled into the optical-fiber.

Abstract: An optical wave guide path recording medium includes an optical wave guide path recording layer including an optical wave guide path and an input light coupling portion for introducing a light beam, the optical wave guide path having a plurality of refractive index discontinuous portions arranged thereon, wherein at least one of a shape and a relative distance of the refractive index discontinuous portions is formed based on information to be recorded; and a light transmitting elastic body layer disposed apart from the optical wave guide path recording layer at such a distance that when the refractive index discontinuous portions generate a reflected wave guide light after the light beam is introduced into the optical wave guide path, evanescent wave coupling of the reflected wave guide light is induced with the optical wave guide path recording layer and the reflected wave guide light is transmitted to the light transmitting elastic body layer, the light transmitting elastic body layer having an output light

Abstract: A side-polished fiber/overlay waveguide architecture and process for non-invasively implementing an optical amplifier are provided for an optical communications system. A "channel" overlay waveguide is employed to constrain for amplification optical energy evanescently coupled to the overlay waveguide from the side-polished optical fiber. One of two amplification methods can be employed. The first involves inducing stimulated emission with the overlay waveguide and the second uses a second order, non-linear frequency conversion to down-convert a high-power, short-wavelength pump signal into the waveguide to amplify the optical energy coupled thereto. Amplification of optical energy in the channel overlay waveguide can be established within a single beat length of evanescent removal to evanescent return of the optical energy to the side-polished fiber optic.

Abstract: A coplanar waveguide polymeric in-line fiber construct (CPW-PILF) formed on an optic half coupler substrate base or D-fiber wherein the surface is polished down through the cladding on the optical fiber so as to form an evanescent coupling region on the surface. Co-planar, spaced-apart electrodes are deposited on the surface with their gap aligned over the coupling region, and an electro-optic (EO) polymeric waveguide is deposited over the electrodes and between the electrode gap. Light transmitted thorough the optical fiber is evanescently coupled to said waveguide and modulated by a signal applied to the electrodes. Alternatively, the waveguide is deposited on the surface of the substrate and the electrodes are deposited over the waveguide.

Abstract: A very high temperature microbeam sensor of a resonant integrated microstructure having an electrostatic beam driver and an optical fiber pick-up for sensed light from the beam. The high temperature sensor has no components that are vulnerable to temperatures up to 600 degrees C. Associated components for detection, processing and driving are remote from the sensor environment. By using different materials in the beam assembly, such as tungsten for the beam, and sapphire for the substrate and the shell, the sensor can withstand temperatures up to 1000 degrees C. Also, optical fiber may be used for long distance connections between processing electronics and the driver in the sensing device, by locating a photo detector just outside the very or ultra high temperature sensing environment, and then using optical fiber for sending long distance signals from the processor to the driver photo detector, for eliminating electrical signal-to-noise problems.

Abstract: A compound waveguide device having a channel waveguide in optical proximity to an elongate waveguide propagating an optical signal therein is disclosed. The channel waveguide includes a coupling surface through which optical energy is evanescently coupled to or from the optical signal propagating in the elongate waveguide. The channel waveguide is shaped to confine distribution of the optical energy therein along axes transverse to the axis of propagation of the optical energy. Transverse diffraction of the optical energy within the channel waveguide is thereby limited. In one embodiment, the elongate waveguide is a side-polished fiber optic waveguide. Electro-optic control of the compound waveguide is disclosed, as are bandstop, bandpass and detection configurations thereof.

Abstract: An optical coupling device, or a compound waveguide, in which optical energy is coupled to or from an optical signal propagating along a transmitting waveguide is disclosed. The optical coupling device includes a thin film organic crystal waveguide positioned in optical proximity to a portion of the transmitting waveguide. The organic crystal waveguide has a first, coupling surface facing the transmitting waveguide through which the optical energy is coupled. The transmitting waveguide may be a fiber optic having at least some material removed along a side thereof to facilitate the coupling of optical energy between the fiber optic and the organic crystal waveguide. Polishing and lapping methods for producing the thin film organic crystal waveguide, with optically smooth surfaces, are also disclosed, as are organic salt implementations of the organic crystal.

Abstract: A waveguide coupler comprises at least a first waveguide coupled at a coupling region to a second waveguide such that at least a part of radiation propagating along the first waveguide is coupled into the second waveguide. The second waveguide comprises a diffraction grating disposed at the coupling region to inhibit coupling of radiation from the first waveguide into the second waveguide at wavelengths characteristic of the diffraction grating.