Abstract: An optoelectronic system for measuring fluorescence or luminescence emission decay, including (a) a light source being a light emitting diode, a semiconductor laser or a flash tube; (b) a first integrated circuit comprising at least one circuit causing the light source to emit light pulses towards a sample which causes a fluorescence or luminescence emission from the sample; (c) a photodiode detecting the emission; (d) a second integrated circuit comprising a detection analysis system determining information about the sample by analyzing decay of the detected emission; and (e) an enclosure enclosing the light source, the first integrated circuit, the second integrated circuit and the photodiode.

Abstract: A variable focal length light source is constructed using a tunable focus length lens which can be adjusted in synchronization to the focal length of a camera lens. In one embodiment, a deformable lens is used in conjunction with an LED light source to provide the tunable focal length required for a camera flash device.

Abstract: A diagnostic assay reader includes a detector configured to read a diagnostic assay result and develop a result signal that is indicative of the result, a processor configured to process the result signal, and an external power interface connected to the detector and to the processor, the external power interface configured to receive external power for the diagnostic assay reader.

Abstract: First and second substrates are spaced apart and joined around a perimeter to define a gas chamber between the substrates. The first substrate is made of a material that transmits visible radiation. A layer of a phosphor material overlies an interior surface of one of the substrates and is capable of converting UV radiation to visible radiation. A layer of a reflective material overlies an interior surface of the other one of the substrates.

Abstract: A method to calibrate measurements of a test analyte in a test sample including measuring at least one test-light level responsive to reactions of at least one reagent group and at least one reactive test analyte in the test sample and measuring at least one control-light level responsive to reactions of at least one reagent group and at least one control analyte in a control sample. Each control analyte is a known amount of at least one reactive test analyte. The method further includes determining a presence of the reactive test analyte in the test sample based on the measured test-light levels and control-light levels. The reagent group and the reactive test analyte react by attaching to each other.

Abstract: A projection optical system for digital lithography. The system includes an Offner imaging system defining an optical axis and having a well-corrected region. The system also includes spatial light modulators circumferentially arranged about the optical axis, such that optical beams emitted thereby propagate through the Offner imaging system within the well-corrected region.

Abstract: A position detection system. In representative embodiments, the position detection system comprises a support structure having a cavity, a first light source configured to emit light into at least part of the cavity, a second light source configured to emit light into at least part of the cavity, a first image sensor configured to capture at least part of the light emitted into the cavity by the first and second light sources, an article moveable relative to the support structure, a protuberance attached to the article, and a computation circuit configured to receive a signal from the first image sensor. Movement of the support structure moves the protuberance within the cavity. The computation circuit is configured to compute the location of the protuberance from shadows cast by the protuberance onto the first image sensor.

Abstract: A light emitting device has a light emitting diode (LED), a reflector cup, and one or more adjustment mechanisms to control the intensity profile of light emitted from the light emitting device. The reflector cup has a base and a sidewall extending outward from the base. A base adjustment mechanism controls the total amount of light reflected from the base and into the beam of light emitted from the light emitting mechanism by controlling the aggregate reflectivity of the base. A sidewall adjustment mechanism controls the angle of the sidewall relative to the base. A vertical adjustment mechanism vertically raises or lowers the LED relative to the base.

Abstract: An object to be imaged or detected is illuminated by a single broadband light source or multiple light sources emitting light at different wavelengths. The light is detected by a detector, which includes a light-detecting sensor covered by a hybrid filter. The hybrid filter includes a multi-band narrowband filter mounted over a patterned filter layer. The light strikes the narrowband filter, which passes light at or near the multiple wavelengths of interest while blocking light at all other wavelengths. The patterned filter layer alternately passes the light at one particular wavelength while blocking light at the other wavelengths of interest. This allows the sensor to determine either simultaneously or alternately the intensity of the light at the wavelengths of interest. Filters may also be mounted over the light sources to narrow the spectra of the light sources.

Abstract: Embodiments of the invention involve UV resistant liquid crystal cells. One embodiment of the invention is to increase the volume of the liquid crystal material that is stored inside the cell. For example, trenches may be used to provide reservoirs that hold the additional liquid crystal material. The inventive cell can be used as a SLM in photolithographic imaging systems.

Abstract: A projection optical system for digital lithography includes an Offner imaging system with a defined optical axis. The Offner imaging system has a well-corrected region. The system includes means for shaping an optical beam having an extent too large to fit within the well-corrected region to propagate through the Offner imaging system within the well-corrected region.

Abstract: The optical module optically aligns two adjacently located optical components. The optical module comprises a substrate and at least one pre-alignment groove formed therein for coarsely aligning the two optical components. The optical components are seated in the at least one groove with a gap between them. The optical module further comprises a waveguide core located in the gap between the two optical components. The waveguide core extends from a light-guiding portion of one optical component to a light-guiding portion of the other optical component and guides light from one optical component to the other.

Abstract: Optical systems that include optical fiber splices are provided. Such an optical system includes first and second optical fibers, each of which has an end surface and a side surface adjacent to the end surface. An adhesive joins the end surface of the first optical fiber to the end surface of the second optical fiber. Additionally, at least a portion of the end surface of the first optical fiber exhibits a wettability for the adhesive that is higher than a wettability for the adhesive exhibited by at least a portion of the side surface of the first optical fiber. Methods and other systems also are provided.

Abstract: An apparatus and method for spectral dispersion compensation in an optical communication network are disclosed. In one embodiment, the invention comprises an optical medium having a signal distributed over a plurality of wavelengths, a demultiplexer adapted to receive the plurality of wavelengths and divide the plurality of wavelengths into individual wavelengths, and a plurality of dispersion compensation elements each adapted to receive a wavelength. The dispersion compensation elements alter the timing of each wavelength, where the plurality of dispersion compensation elements operates on all wavelengths simultaneously. The invention also comprises a multiplexer adapted to receive each individual wavelength and combine the individual wavelengths onto the optical medium.

Abstract: A personal display system having an ocular scan unit for generating user identification information and an interface for conveying user identification to a connected system.

Abstract: The optical module optically aligns two adjacently located optical components. The optical module comprises a substrate and at least one pre-alignment groove formed therein for coarsely aligning the two optical components. The optical components are seated in the at least one groove with a gap between them. The optical module further comprises a waveguide core located in the gap between the two optical components. The waveguide core extends from a light-guiding portion of one optical component to a light-guiding portion of the other optical component and guides light from one optical component to the other.

Abstract: Optical systems that include optical fiber splices are provided. Such an optical system includes first and second optical fibers, each of which has an end surface and a side surface adjacent to the end surface. An adhesive joins the end surface of the first optical fiber to the end surface of the second optical fiber. Additionally, at least a portion of the end surface of the first optical fiber exhibits a wettability for the adhesive that is higher than a wettability for the adhesive exhibited by at least a portion of the side surface of the first optical fiber. Methods and other systems also are provided.

Abstract: A multiple wavelength output light source is disclosed. The multiple wavelength output light source comprises a laser device having a plurality of output wavelengths, and a modulator associated with and configured to modulate each wavelength independently. The plurality of modulated wavelengths can be separated prior to modulating and then combined, after modulation, onto a single optical fiber. The multiple modulated laser outputs can be used in a WDM or a DWDM optical communication system.

Abstract: A ferroelectric liquid crystal-based light valve system with contrast control and a method for controlling contrast in a ferroelectric liquid crystal-based light valve system. The light valve system includes a light input, a ferroelectric liquid crystal-based spatial light modulator, an analyzer, and a voltage controller. The ferroelectric liquid crystal-based spatial light modulator includes signal processing electronics and an array of pixels. The array of pixels is configured to receive light from the light input and includes an array of pixel electrodes, a transparent electrode, and a layer of ferroelectric liquid crystal material. Each pixel electrode is independently switchable between a first voltage level and a second voltage level by the signal processing electronics. One of these levels may be a variable input voltage level. The analyzer has orthogonal directions of maximum transmissivity and minimum transmissivity.

Abstract: A color, high-throughput, ferroelectric liquid crystal-based light valve comprising a light input, a light output, a beam splitter, a color separator, reflective spatial light modulators, and a switchable half-wave plate. Light polarized parallel to a first direction is received through the light input. Light from the light input and reflected by the spatial light modulators is output from the light output. The reflective spatial light modulators are structured as a quarter-wave plates and each has a principal axis that switches through an angle &phgr;. The beam splitter has orthogonal directions of maximum transmissivity and maximum reflectivity, one of which is parallel to the first direction.