Abstract: The disclosure provides a method of forming an erasable optical coupler in a photonic device comprising a conventional optical waveguide formed in a crystalline wafer. The method comprises selectively implanting ions in a localized region of the wafer material adjacent to the conventional waveguide of the photonic device, to cause modification of the crystal lattice structure of, and a change in refractive index in, the ion implanted region of the wafer material to thereby form an ion implanted waveguide optically coupled to the adjacent conventional waveguide to couple light out therefrom, or in thereto. The crystalline wafer material and ion implanted waveguide are such that the crystal lattice structure or composition can be modified to adjust or remove the optical coupling with the conventional waveguide by further modification of the refractive index in the ion implanted region.

Abstract: The disclosure provides a method of forming an erasable optical coupler in a photonic device comprising a conventional optical waveguide formed in a crystalline wafer. The method comprises selectively implanting ions in a localized region of the wafer material adjacent to the conventional waveguide of the photonic device, to cause modification of the crystal lattice structure of, and a change in refractive index in, the ion implanted region of the wafer material to thereby form an ion implanted waveguide optically coupled to the adjacent conventional waveguide to couple light out therefrom, or in thereto. The crystalline wafer material and ion implanted waveguide are such that the crystal lattice structure or composition can be modified to adjust or remove the optical coupling with the conventional waveguide by further modification of the refractive index in the ion implanted region.

Abstract: A system for measuring thermal degradation of composites includes a cylindrical body; a bottom cover having a lower central aperture; an upper concave mirror facing the bottom cover with an upper central orifice concentric with a central axis of the body; a lower concave mirror facing the upper concave mirror with a lower central orifice concentric with the central axis; a source of actinic radiation between the upper concave mirror and the lower concave mirror on the central axis to direct actinic radiation through the lower central orifice and lower central aperture; and a camera with an image sensor positioned concentrically relative to the upper central orifice; wherein the bottom cover is adjustable relative to the cylindrical body to provide a focusing function for the image sensor by varying the distance from the lower central orifice and the upper reflective surface.

Abstract: A system for measuring thermal degradation of composites includes a cylindrical body; a bottom cover having a lower central aperture; an upper concave mirror facing the bottom cover with an upper central orifice concentric with a central axis of the body; a lower concave mirror facing the upper concave mirror with a lower central orifice concentric with the central axis; a source of actinic radiation between the upper concave mirror and the lower concave mirror on the central axis to direct actinic radiation through the lower central orifice and lower central aperture; and a camera with an image sensor positioned concentrically relative to the upper central orifice; wherein the bottom cover is adjustable relative to the cylindrical body to provide a focusing function for the image sensor by varying the distance from the lower central orifice and the upper reflective surface.

Abstract: A system for measuring thermal degradation of composites, may include a housing having an interior with an opening shaped to expose a test area of the composite to be tested to the interior; a light-emitting diode that emits primarily ultraviolet radiation, the diode mounted on the housing to direct the ultraviolet radiation into the interior and through the opening; an image sensor mounted on the housing and open to the interior to receive radiation emitted from the test area passing through the opening into the interior; and an image processor connected to receive a signal from the image sensor, the image processor determining a presence or absence of thermal degradation of the test area in response to the signal.

Abstract: A floating monitoring apparatus and system comprising: a base; a first flotation device attached to the base and located generally below the base, the flotation device configured to float on a surface of water; a light support member extending downward from the base, and configured to be at least partially below the surface of water; a camera attached to the base and configured to be aimed to capture images of a target below the base, where the camera is generally kept above the surface of the water; a light source attached to the light support member, and configured to direct light to illuminate the target, the lights located below the surface of the water.

Abstract: A system for measuring thermal degradation of composites, may include a housing having an interior with an opening shaped to expose a test area of the composite to be tested to the interior; a light-emitting diode that emits primarily ultraviolet radiation, the diode mounted on the housing to direct the ultraviolet radiation into the interior and through the opening; an image sensor mounted on the housing and open to the interior to receive radiation emitted from the test area passing through the opening into the interior; and an image processor connected to receive a signal from the image sensor, the image processor determining a presence or absence of thermal degradation of the test area in response to the signal.

Abstract: A floating monitoring apparatus comprising: a base; a first flotation device attached to the base and located generally below the base, the flotation device configured to float on a surface of water; a light support member extending downward from the base, and configured to be at least partially below the surface of water; a camera attached to the base and configured to be aimed to capture images of a target below the base, where the camera is generally kept above the surface of the water; a light source attached to the light support member, and configured to direct light to illuminate the target, the lights located below the surface of the water.

Abstract: A compact, battery powered video imaging device for use in XYZ stage equipped machines (such as milling machines, jig borers, coordinate measuring machines, etc.) that mounts into the spindle of such a machine and displays a magnified image of a part on the XYZ stage of the machine on an integrated video monitor such as a Liquid Crystal Display panel equipped with crosshairs or similar reference marks. The XYZ stage of the host machine is used to move the part so that various features of the part are brought into the crosshairs of the video monitor. In such a way the XYZ coordinates of various features of the part with respect to a selected reference feature, displayed on the host machine's position readout, can be obtained. This procedure can be used to aid work piece setup, measure parts in-process without disturbing the setup, or to inspect finished parts for dimensional accuracy.

Abstract: The present invention is a multipass unipoint optical cell used for the improved analysis of samples by transmission, reflection, Raman or fluorescence spectroscopy by the multiple reimaging of light through the same analysis point. The cell comprises two or more identical optical reimaging elements each consisting of two symmetrically opposing, identical, confocal, and coaxial parabolic reflective surfaces. These reimaging optical elements can be arranged around the common focal point, which thus becomes the analysis point, to form different multipass unipoint optical cell configurations, all the passes crossing in the analysis point where a sample is brought to interact with light, the effect of said interaction being enhanced in proportion to the number of passes.

Abstract: The present invention relates to a transmission liquid flow cell capable of high rates of liquid flows regardless of the optical pathlength of the cell. This increase in the cell's internal flow rate is provided by an internal bypass created around the circumference of the windows. The high rate of internal flow of liquid around the circumference of the windows and in direct contact with the liquid between the windows provides a push-pull action that urges the flow of liquid through the gap between the windows. The faster the circumferential flow, the stronger the push-pull action. The cell is used for the measurement of the absorption of light passing through a liquid sample contained in the gap between the cell's windows.

Abstract: A reach-adjustable lever assembly that is mountable to a handlebar for actuating one of a gear-change and braking device. The lever assembly includes a lever with a finger grip pivotably connected to a housing and a reach adjust mechanism. The reach adjust mechanism includes a cam actuator and a cam. The cam actuator is rotatably supported by one of the housing and the lever. The cam is threadably connected to the cam actuator and is configured to engage the other of the housing and the lever. The cam is displaceable upon rotation of the cam actuator to pivot the lever to position the finger grip relative to the handlebar.

Abstract: An optical reimaging element comprising: a first off-axis parabolic mirror having only the portion of the mirror surface below the first plane that passes through its focal point and is perpendicular to the axis of the first parabola associated with the first mirror, the portion of the first mirror being on the same side of the first plane as the vertex of the first parabola; a second off axis parabolic mirror identical to the first mirror also having only the portion of the mirror surface below the second plane that passes through its focal point and is perpendicular to the axis of the second parabola associated with the second mirror, the portion of the second mirror being on the same side of the second plane as the vertex of the second parabola; and the first and second mirrors being in optical communication with each other so that their first and second planes coincide and so that their parabolic mirror surfaces are symmetrically opposing, confocal, and coaxial thereby having the property that a ray of li

Abstract: The present invention is an optical device for small spot analysis by diffuse reflectance using fiber optic interfaced spectrometers. The device comprises a source of electromagnetic radiation and a set of mirrors designed to project most of the radiation from the said source onto a less than 1 mm diameter spot on the sample, collect a portion of the radiation reflected by the sample and refocus this reflected radiation into an optical fiber. The said optical fiber then brings the said reflected radiation into a fiber optic interfaced spectrometer for spectral analysis. A means for the magnified viewing of the sample and the precise selection of the sampling spot for analysis is integrated into the invented device. Adding a digital camera and a laser module to the said device enables nearly simultaneous multimodal analysis of the same sampling spot by diffuse reflectance, Raman, and fluorescence spectroscopy and by image analysis.

Abstract: A reach-adjustable lever assembly that is mountable to a handlebar for actuating one of a gear-change and braking device. The lever assembly includes a lever with a finger grip pivotably connected to a housing and a reach adjust mechanism. The reach adjust mechanism includes a cam actuator and a cam. The cam actuator is rotatably supported by one of the housing and the lever. The cam is threadably connected to the cam actuator and is configured to engage the other of the housing and the lever. The cam is displaceable upon rotation of the cam actuator to pivot the lever to position the finger grip relative to the handlebar.

Abstract: The present invention is a multipass unipoint optical cell used for the improved analysis of samples by transmission, reflection, Raman or fluorescence spectroscopy by the multiple reimaging of light through the same analysis point. The cell comprises two or more identical optical reimaging elements each consisting of two symmetrically opposing, identical, confocal, and coaxial parabolic reflective surfaces with the property to refocus any ray of light coming from the common focal point onto one of the parabolic surfaces, back to the same focal point by the other parabolic surface at an angle to the incoming ray. Two or more of these reimaging optical elements can be configured around the common focal point to form different multipass unipoint optical cell configurations, all the passes crossing in the analysis point where a sample is brought to interact with light, the effect of said interaction being enhanced in proportion to the number of passes.

Abstract: A crystal assembly for optical analyzation of samples includes a first crystal member and a second crystal member, the latter of which is preferably a diamond. The first and second crystal members, which have substantially the same index of refraction for infrared energy, are coupled together at an optically transmitting interface. This interface may be formed by crystal surfaces in intimate contact with one another or by a third crystal member positioned therebetween. The first crystal member has at least one circumferential sidewall focusing surface for redirecting infrared energy within the first crystal member to and from a focal ring or focal plane at or near the optical interface. The focused infrared energy transmitted from the first crystal member is internally reflected within the second crystal member to obtain encoding specific to a sample in contact with a surface of the second crystal member.

Abstract: An apparatus and method for spectroscopic or radiometric analysis of solid, liquid, or gas samples includes first and second optically transmitting materials. The first optically transmitting material has selected bulk optical transmission and index of refraction properties which enable infrared radiation transmission therethrough across selected optical transmission ranges. The first optically transmitting material is of a type which normally has chemical or mechanical degradation when in contact with the sample during spectroscopic or radiometric analysis. The second optically transmitting material is preferably a wafer or thin sheet in optical/mechanical contact with the first optically transmitting material. The second material is designed to be located between the first optically transmitting material and the sample all held in a fixture or fixtures to prevent the sample from contacting the first material during spectroscopic or radiometric analysis of the sample.

Abstract: A crystal assembly for optical analyzation of samples includes a first crystal member and a second crystal member, the latter of which is preferably a diamond. The first and second crystal members, which have substantially the same index of refraction for infrared energy, are coupled together at an optically transmitting interface. This interface may be formed by crystal surfaces in intimate contact with one another or by a third crystal member positioned therebetween. The first crystal member has at least one circumferential sidewall focusing surface for redirecting infrared energy within the first crystal member to and from a focal ring or focal plane at or near the optical interface. The focused infrared energy transmitted from the first crystal member is internally reflected within the second crystal member to obtain encoding specific to a sample in contact with a surface of the second crystal member.

Abstract: An optical accessory for reflection spectroscopy having a very small sampling area and provided with a microscope for aiding the user to locate a sample to be analyzed on the active sampling area where it can interact with a radiation beam. The microscope is characterized by fiber optic bundles to supply sample illumination via a cone-shaped light-funnelling tip terminated in a thin hard optically transparent wear tip, e.g., of sapphire. The microscope is also used to apply pressure via the wear tip to the sample while it is being illuminated and while it can be viewed to maximize interaction with the radiation.