Abstract: This invention provides an angled-dual-axis confocal scanning microscope comprising a fiber-coupled, angled-dual-axis confocal head and a vertical scanning unit. The angled-dual-axis confocal head is configured such that an illumination beam and an observation beam intersect optimally at an angle &thgr; within an object. The vertical scanning unit causes the angled-dual-axis confocal head to move towards or away from the object, thereby yielding a vertical scan that deepens into the object, while keeping the optical path lengths of the illumination and observation beams unchanged so to ensure the optimal intersection of the illumination and observation beams in the course of vertical scanning. The angled-dual-axis confocal scanning microscope may further comprises a transverse stage, causing the object to move relative to the angled-dual-axis confocal head along transverse directions perpendicular to the vertical direction, thereby producing a transverse scan.

Abstract: An ellipsoidal solid immersion lens (ESIL) for use as a collimator for a waveguide. The ESIL has a refractive index n, an ellipsoidal surface portion defining a geometrical ellipsoid with geometrical foci F1, F2 along a major axis of length M. The ESIL has an attachment surface portion for joining to the waveguide. The attachment surface portion passes near or through the second geometrical focus F2. The geometrical foci F1, F2 are separated by a distance S=M/n, such that a substantially collimated light beam exhibiting a Gaussian type intensity profile propagating along the major axis M and entering the ESIL through the ellipsoidal surface portion converges to a Gaussian beam waist substantially at the second geometrical focus F2.

Abstract: An apparatus and method for performing optical coherence domain reflectometry. The apparatus preferably includes a single output light source to illuminate a sample with a probe beam and to provide a reference beam. The reference beam is routed into a long arm of an interferometer by a polarizing beamsplitter. A reflected beam is collected from the sample. A 90° double pass polarization rotation element located between the light source and the sample renders the polarizations of the probe beam and reflected beam orthogonal. The polarizing beamsplitter routes the reflected beam into a short arm of the interferometer. The interferometer combines the reference beam and the reflected beam such that coherent interference occurs between the beams. The apparatus ensures that all of the reflected beam contributes to the interference, resulting in a high signal to noise ratio.

Abstract: An apparatus and method for performing optical coherence domain reflectometry. The apparatus preferably includes a single output light source to illuminate a sample with a probe beam and to provide a reference beam. The reference beam is routed into a long arm of an interferometer by a polarizing beamsplitter. A reflected beam is collected from the sample. A 90° double pass polarization rotation element located between the light source and the sample renders the polarizations of the probe beam and reflected beam orthogonal. The polarizing beamsplitter routes the reflected beam into a short arm of the interferometer. The interferometer combines the reference beam and the reflected beam such that coherent interference occurs between the beams. The apparatus ensures that all of the reflected beam contributes to the interference, resulting in a high signal to noise ratio.

Abstract: An apparatus and method for performing optical coherence domain reflectometry. The apparatus preferably includes a single output light source to illuminate a sample with a probe beam and to provide a reference beam. The reference beam is routed into a long arm of an interferometer by a polarizing beamsplitter. A reflected beam is collected from the sample. A 90° double pass polarization rotation element located between the light source and the sample renders the polarizations of the probe beam and reflected beam orthogonal. The polarizing beamsplitter routes the reflected beam into a short arm of the interferometer. The interferometer combines the reference beam and the reflected beam such that coherent interference occurs between the beams. The apparatus ensures that all of the reflected beam contributes to the interference, resulting in a high signal to noise ratio.

Abstract: An apparatus and method for performing optical coherence domain reflectometry. The apparatus preferably includes a single output light source to illuminate a sample with a probe beam and to provide a reference beam. The reference beam is routed into a long arm of an interferometer by a polarizing beamsplitter. A reflected beam is collected from the sample. A 90° double pass polarization rotation element located between the light source and the sample renders the polarizations of the probe beam and reflected beam orthogonal. The polarizing beamsplitter routes the reflected beam into a short arm of the interferometer. The interferometer combines the reference beam and the reflected beam such that coherent interference occurs between the beams. The apparatus ensures that all of the reflected beam contributes to the interference, resulting in a high signal to noise ratio.

Abstract: An apparatus uses reflectance spectrophotometry to characterize a sample having any number of thin films. The apparatus uses two toroidal mirrors in an optical relay to direct light reflected by the sample to a spectroscopic device. A computer then analyzes the reflected spectrum to characterize the optical properties of the sample. The optical relay allows a range of angles of reflection from the sample, and has no chromatic aberration. The optical relay is also arranged so that the non-chromatic aberration is minimized. For polarization-based measurements polarizing elements can be used in the apparatus and the spectroscopic device can be a spectroscopic ellipsometer. The sample is mounted on a movable stage so that different areas of the sample may be characterized. Furthermore, a deflector and a viewer are used to allow the operator of the apparatus to view the region of the sample under study.

Abstract: An optical device for measuring reflectance, and, optionally, transmission, of a substrate. The device has first and second toroidal mirrors and first and second optical fibers. The first toroidal mirror directs light from the first optical fiber toward the substrate, which reflects from the substrate and is collected by the second toroidal mirror. The light collected by the second toroidal mirror is focused into the second optical fiber. There are many possible orientations for the fibers and mirrors. The device may also have a fold mirror for directing the light toward the substrate. Optionally, the present invention includes components for measuring transmission of the substrate. The components for measuring transmission may include fibers and toroidal mirrors. Preferably, reflectance and transmission are measured at the same location. If a fold mirror is used, the fold mirror has a gap to allow transmission measurements to be performed at the same location as reflectance measurements.

Abstract: An apparatus uses reflectance spectrophotometry to characterize a sample having any number of thin films. The apparatus uses two toroidal mirrors in an optical relay to direct light reflected by the sample to a spectrophotometer. A computer then analyzes the reflected spectrum to characterize the optical properties of the sample. The optical relay allows a range of angles of reflection from the sample, and has no chromatic aberration. The optical relay is also arranged so that the non-chromatic aberration is minimized. The sample is mounted on a movable stage so that different areas of the sample may be characterized. Furthermore, a deflector and a viewer are used to allow the operator of the apparatus to view the region of the sample under study.

Abstract: The invention comprises an apparatus for characterizing a thin film using the reflected spectrum of the film. The apparatus uses two toroidal mirrors in an optical relay to direct light onto the thin film and to direct reflected light from the film to a spectrophotometer. A computer then analyzes the reflected spectrum to characterize the optical properties of the thin film. The optical relay allows for a range of angles of incidence upon the sample, and has no chromatic aberration.

Abstract: A variable stroke engine includes first and second pistons mounted in respective cylinders for reciprocal linear movement. The engine also includes first, second, and third parallel crankshafts. A first connecting assembly connects the first piston to the first and second crankshafts. A second connecting assembly connects the second piston to the second and third crankshafts. Each connecting assembly includes first and second connecting rods arranged in a crossing relationship with each other. A first set of synchronizing gears establishes co-rotation of the first and second crankshafts and synchronizes a first angular phase relationship between the first and second crankshafts. A second set of synchronizing gears establishes co-rotation of the second and third crankshafts and synchronizes a second angular phase relationship between the second and third crankshafts.

Abstract: A variable stroke engine has a piston slidably mounted in a cylinder for reciprocal linear movement therein. The engine includes first and second parallel crankshafts having first and second crank pins, respectively. A connecting assembly connects the piston to the first and second crankshafts. The connecting assembly includes an oscillating member pivotally connected to the piston at a first connection. The assembly further includes first and second connecting rods rotatably connected to the first and second crank pins, respectively. The first and second connecting rods are further rotatably connected to the oscillating member at respective second and third connections. The second and third connections are offset from the first connection and offset from each other such that the first and second connecting rods are arranged in a crossing relationship. Synchronizing gears establish co-rotation of the first and second crankshafts and synchronize an angular phase relationship between the crankshafts.

Abstract: A laser system including a lasing medium (gas, liquid or solid) in an annular configuration with means defining a stationary lasing region in a portion of the lasing medium and means for rotating the lasing medium to rotate heated portions of the medium into heat exchange relationship with the surrounds for cooling and bringing cooled portions of the medium into the lasing region.