Abstract: A 3D OCT confocal imaging apparatus includes a light source module for providing an illumination beam with wider bandwidth from a crystal fiber; a reference source module; a pickup module; a beam splitter; an optical filter; and a sensor module. When the illumination beam illuminates a sample, a pickup objective lens and a piezoelectric actuator of the pickup module together provide an image beam scanning the sample in depth direction. The image beam and a reference beam from the reference source module together form an interference image beam, which is converted by a photosensor into a coherence image electric signal. Meanwhile, the interference image beam passes through a pinhole to form a confocal image, which is converted by an excited light photometer into a confocal image electric signal. With an image processing system, a 3D OCT confocal microscopic image of the sample can be produced from these image electric signals.

Abstract: A system and method for locating and identifying unknown samples. A targeting mode may be utilized to scan regions of interest for potential unknown materials. This targeting mode may interrogate regions of interest using SWIR and/or fluorescence spectroscopic and imaging techniques. Unknown samples detected in regions of interest may be further interrogated using a combination of Raman and LIBS techniques to identify the unknown samples. Structured illumination may be used to interrogate an unknown sample. Data sets generated during interrogation may be compared to a reference database comprising a plurality of reference data sets, each associated with a known material. The system and method may be used to identify a variety of materials including: biological, chemical, explosive, hazardous, concealment, and non-hazardous materials.

Abstract: An apparatus includes first and second light sources for respectively generating broadband and monochromatic lights, a beamsplitter optically coupled to the first light source for splitting the broadband light into a reference light and a sample light, a reference arm optically coupled to the beamsplitter for receiving the reference light and returning the received reference light into the beamsplitter, a sample arm optically coupled to the beamsplitter and the second light source for combining the sample and monochromatic lights, delivering the combined light to the target of interest, collecting a backscattering light and a Raman scattering light generated from interaction of the combined light with the target of interest, returning the backscattering light into the beamsplitter so as to generate an interference signal between the returned backscattering light and the returned reference light in the beamsplitter, and directing the Raman scattering light in an output optical path.

Abstract: A method and device for the detection and monitoring of the contamination of an optical component in a device for laser material processing, which emits a process laser beam through or onto the optical component. A measurement beam emitted by a light source is projected under an angle of incidence onto an optical surface of the optical component. The beam reflected from the outer surface of the protective window under the angle of reflection corresponding to the angle of incidence is conducted through an aperture stop onto a first light-sensitive detector so as to record the intensity of the reflected beam. The intensity of the scattered radiation, scattered diffusely from the optical surface of the component under a scattering angle, is recorded by a second light-sensitive detector. The degree of the contamination of the component is determined from the recorded intensities of the reflected beam and the scattered radiation.

Abstract: In a method and an apparatus for inspecting a surface of a disk, a disk that is a sample is rotated, and a light beam is applied to the sample while moving the sample in the direction perpendicular to the center axis of rotation. Light reflected and scattered from the sample in a first direction is detected to obtain a first detection signal while applying the light beam. Light reflected and scattered from the sample in a second direction is detected to obtain a second detection signal while applying the light beam. The first detection signal and the second detection signal are processed to detect a defect on the sample. A preset threshold is compared with the output level of the first detection signal or the output level of the second detection signal to determine whether the material of the disk that is the sample is a predetermined material.

Abstract: The invention relates to an apparatus and a method for determining a height map of a surface of an object. The apparatus can include positioning means for the object, a light source, an optical detector for converting the received light into electrical signals, first optics for directing light from the light source to the surface and for directing the light from the surface to the optical detector, a beam splitter located between the first optics and the surface, a reference mirror, second optics located between the beam splitter an the mirror for directing the light from the beam splitter to the mirror and from the mirror to the beam splitter, scanning means, processing means that converts the signal from the optical detector into a height map. The beam splitter can be a polarizing beam splitter. A controllable polarization controller can be located between the light source and the first optics.

Abstract: Methods and devices provide for transmitting a series of optical signals within a range of an O-band through a U-band into a device under test comprising one or more passive optical components; measuring powers of the optical signals that propagated through the device under test; calculating wavelength-dependent insertion loss values based on the measured power of the optical signals; measuring powers of reflected portions of the optical signals that propagated through the device under test; and calculating wavelength-dependent return loss values based on the measured powers of the reflected portion of the optical signal.

Abstract: A drawing apparatus includes a charged particle optical system, a first measurement device including an image taking optical system and configured to measure a position of a reference mark in a first direction, a second measurement device configured to measure a position of the reference mark in the first direction based on an amount of charged particle beams that arrives thereat from the reference mark on which the charged particle beam are incident. The reference mark includes a first region having a first edge inclined with respect to a second direction perpendicular to the first direction and a second region having a second edge parallel to the second direction. A processor obtains a baseline based on measurement result with respect to the first region obtained by the first measurement device and measurement result with respect to the second region obtained by the second measurement device.

Abstract: A detection apparatus, which detects a mark formed on a lower surface of a target object, includes: a first detector which illuminates the mark from an upper surface side of the target object to detect an image of the illuminated mark; a second detector which detects an upper surface position of the target object; and a processor which obtains information indicating a focus position to focus on the mark in the first detector, based on the upper surface position detected by the second detector.

Abstract: A laser tracker system for measuring six degrees of freedom may include a main optics assembly structured to emit a first laser beam, a pattern projector assembly structured to emit a second laser beam shaped into a two-dimensional pattern, and a target. The target may include a retroreflector and a position sensor assembly. A center of symmetry of the retroreflector may be provided on a different plane than a plane of the position sensor assembly. A method of measuring orientation of a target may include illuminating the target with a laser beam comprising a two-dimensional pattern, recording a position of the two-dimensional pattern on a position sensor assembly to create a measured signature value of the two-dimensional pattern, and calculating an orientation of the target based on the measured signature value.

Abstract: Provided is a roughness evaluating apparatus including: a generating unit configured to generate an electromagnetic wave pulse; a detecting unit configured to detect the electromagnetic wave pulse from a sample to which the electromagnetic wave pulse is irradiated; a time waveform calculating unit configured to calculate a time waveform of the electromagnetic wave pulse from the sample detected by the detecting unit; and a processing unit configured to obtain roughness information on an internal interface of the sample from the time waveform of the electromagnetic wave pulse, wherein the processing unit extracts a part corresponding to the internal interface in the time waveform of the electromagnetic wave pulse from the time waveform of the electromagnetic wave pulse to obtain the roughness information on the internal interface.

Abstract: Provided is a roughness evaluating apparatus including: a generating unit configured to generate an electromagnetic wave pulse; a detecting unit configured to detect the electromagnetic wave pulse from a sample to which the electromagnetic wave pulse is irradiated; a time waveform calculating unit configured to calculate a time waveform of the electromagnetic wave pulse from the sample detected by the detecting unit; and a processing unit configured to obtain roughness information on an internal interface of the sample from the time waveform of the electromagnetic wave pulse, wherein the processing unit extracts a part corresponding to the internal interface in the time waveform of the electromagnetic wave pulse from the time waveform of the electromagnetic wave pulse to obtain the roughness information on the internal interface.

Abstract: A system for measuring properties of a thin film coated glass having a light source, a spectrometer, at least one pair of probes, a first optical fiber switch and a second optical fiber switch. The pair of probes includes a first probe located on one side of a glass sheet and a second probe located on the opposite side of the glass sheet, directly across from the first probe. The first and second optical fiber switches are adapted to couple either probe to the light source and/or the spectrometer. Because the design of the system is optically symmetrical, calibration may be performed without the use of a reference material such as a tile or mirror. Each of the first and second probes has a first leg and a second leg that are separated from each other by a distance n so that angled reflections may be detected.

Abstract: A system for measuring properties of a thin film coated glass having a light source, a spectrometer, at least one pair of probes, a first optical fiber switch and a second optical fiber switch. The pair of probes includes a first probe located on one side of a glass sheet and a second probe located on the opposite side of the glass sheet, directly across from the first probe. The first and second optical fiber switches are adapted to couple either probe to the light source and/or the spectrometer. Because the design of the system is optically symmetrical, calibration may be performed without the use of a reference material such as a tile or mirror.

Abstract: A polarization imaging apparatus measures the Stokes image of a sample. The apparatus consists of an optical lens set, a first variable phase retarder (VPR) with its optical axis aligned 22.5°, a second variable phase retarder with its optical axis aligned 45°, a linear polarizer, a imaging sensor for sensing the intensity images of the sample, a controller and a computer. Two variable phase retarders were controlled independently by a computer through a controller unit which generates a sequential of voltages to control the phase retardations of the first and second variable phase retarders. A auto-calibration procedure was incorporated into the polarization imaging apparatus to correct the misalignment of first and second VPRs, as well as the half-wave voltage of the VPRs. A set of four intensity images, I0, I1, I2 and I3 of the sample were captured by imaging sensor when the phase retardations of VPRs were set at (0,0), (?,0), (?,?) and (?/2,?), respectively.

Abstract: An entrance denial security system comprises an entrance barrier closing an entrance into a secured area having a plurality of structural tubular elements with hollow cores forming a rigid integral barrier. At least one optical fiber sensor line is laced through the hollow cores of the structural elements for detecting a fault condition signifying an unauthorized intrusion attempt. A processor in communication with the fiber sensor line generates a fault signal in response to the occurrence of a fault condition and identifying the entrance where the fault condition occurred. A communication device operatively associated with the processor communicates the fault signal and an alarm so that a proper security response can be made to the fault condition. The system further comprises a plurality of intrusion sensors disposed at certain locations.

Abstract: An optical imaging system for use with an infusion tube having a drip chamber and an output tube. The drip chamber includes a first portion with a drip tube, a second portion with an exit port, and a third portion between the first and second portions. The optical imaging system includes: an illumination system with at least one light source for emitting light, an optical system, and a memory element storing computer executable instructions. The optical system receives the light transmitted by the output tube or the second portion and transmits data characterizing the received light. The system includes at least one processor configured to execute the computer executable instructions to: detect, using the data, an air bubble in the output tube or the second portion; and determine a volume of the detected air bubble.

Abstract: A spectroscopic system may include: a spectroscopic scatterometer; an angular-resolved spectrometer; and a fiber bundle having a two-dimensional input surface and a one-dimensional output surface.

Abstract: An apparatus for measuring the retroreflectivity of a surface. The apparatus comprises a light source for illuminating an area of said surface at an incident angle relative to the surface; a detector for detecting light reflected back from the surface at an observation angle relative to the surface; a signal processing unit adapted to receive a detector signal from the detector and to determine, from at least the received detector signal, a measure of retro reflectivity of the surface; a range finder for measuring a distance between the apparatus and the illuminated area. The signal processing unit is further adapted to adjust the measure of retroreflectivity responsive to the measured distance.

Abstract: A solar simulator is disclosed having a test chamber for receiving a photovoltaic device for testing, an illumination source for selectively illuminating the photovoltaic device to produce a test signal therefrom, a spectrophotometer for providing a measurement of the spectral distribution of the output of the illumination source, a database containing spectral response information of monitor cell, reference device and DUT, and a computation device for receiving said test signal and said measurement, wherein the computation device converts said test signal into a test value based on said measurement.

Abstract: An optical tracking system for determining the pose of a moving object in a reference coordinate system includes light emitters, optical detectors, and a pose processor. The processor is coupled with an optical detector and also with a light emitter. The processor determines the object's pose according to detected light. An optical detector and a light emitter are situated at a fixed position in the reference coordinate system. Other ones of the optical detectors and light emitters are attached to the object. One optical detector is a (WFOV) detector comprising an optical sensor and optical receptors. The receptors are spaced apart and optically coupled with the optical sensor. The sensor senses light received from a light emitter. Each receptors projects a different angular section of scene on the sensor. The pose processor associates the representation on the sensor, with a respective receptors which projected the light on the sensor.

Abstract: A system and method for determining the pH value of a liquid. The system and method excite the liquid molecules in the liquid by light with a predetermined wavelength and an intensity component, transmitted through the liquid in a predetermined wavelength range, of the light used for excitation is captured. This intensity component is used to produce a wavelength/intensity absorption characteristic and this absorption characteristic is related to a reference absorption characteristic associated with a specific pH value of the liquid. The system and method thus can be used to obtain drinking water from a fuel for aircraft.

Abstract: The invention relates to a device and a method for optical 3D measurement, wherein said device can be switched between a first mode for optical 3D measurement using a chromatic confocal measurement method or the triangulation measurement method and a second mode for colorimetric measurement. In the first mode, a broad-band illuminating beam is focused onto a first plane and in the second mode the broad-band illuminating beam is focused onto a second plane other than the first plane at a distance d from the surface of the object to be measured.

Abstract: Provided herein are devices, systems, methods and various means, including those related to printer systems and, more particularly, relate to methods, apparatuses, systems and other means for monitoring a printer ribbon. Some embodiments use a multi-element detector, which is configured to detect a particular type of light emitted from a light emitter. The multi-state detector can include two sensors, one of which includes a polarizer filter that blocks polarized light. Embodiments can be used to determine, among other things, whether or not a printer ribbon is installed in a printer without the use of a snap plate.

Abstract: A lid for multiwell plates, allowing improved optical measurement of liquid samples within its wells, while mitigating evaporation from said samples, is disclosed. A surface element protrudes from the bottom of the lid into the fluid within a well. The protruding element may be hollow or solid such that light directed into the element may act to capture or direct the beam while preventing backscatter from reaching one or more detectors. The protruding element may direct the beam from the well without requiring the beam to pass through a fluid/air interface. The angle and shape of the lid surfaces and/or light absorbing/blocking colorization may be employed to minimize or eliminate back reflection. Evaporation is controlled by physically capping the well with the lid, either sealing against the face at the top of the well or the inside surface of the well.

Abstract: Brightness factors associated with shade fabric may be utilized when shading a building. A brightness factor may incorporate an openness factor, a visible light reflectance, a diffusion factor, a color, or other characteristics of the shade fabric. The brightness factor may be utilized when selecting a particular shade fabric for a room, building or other location. Additionally, the brightness factor may be utilized by an automated shade control system. The shade fabric selection may affect the building envelope by facilitating the optimization of daylighting, reduction of artificial electric lighting needs, minimization of glare conditions, and reduction of thermal load.

Abstract: A paper sheet identification apparatus capable of identifying an authenticity of a watermark area formed on a paper sheet is provided without increasing the cost. The paper sheet identification apparatus includes: a light receiving part receiving reflected light from a watermarked image formed on a paper sheet to be conveyed, a converter converting the reflected light from the watermarked image received by the light receiving part for each pixel as a unit of a predetermined size including color information having brightness; and an identification processing part identifying the authenticity of the watermarked image based on a correlation coefficient, which is calculated from a density value for each pixel converted by the converter and a density value for each pixel by the transmitted light from the watermarked image of the bill serving as a reference.

Abstract: An optical information analyzer (10) includes a light emitting unit (30) that emits light (excitation light) (L0) to a sample (S), a transmission light receiving unit (50) that receives transmission light (L1), which is the excitation light passing through the sample (S), and detects the received transmission light as a transmission light signal (SG1), scattered light/fluorescence receiving units (60) and (70) that are provided at a plurality of positions, receive side scattered light/fluorescence components (L2) and (L3) from the sample (S), and detect the received side scattered light/fluorescence components as scattered light/fluorescence signals (SG2) and (SG3), and an analyzing unit (90) that measures the optical information of the sample (S) on the basis of the detected scattered light/fluorescence signals (SG2) and (SG3) and the detected transmission light signal (SG1) and analyzes the sample (S) on the basis of the measured optical information.

Abstract: A method of detecting the presence of bacterial spores in a sample comprises non-destructively to the spores carrying out the steps of assessing the absorption, reflectance, and/or index of refraction (IOR) of the sample, subjecting the sample to UV radiation, and reassessing the absorption, reflectance, and/or index of refraction (IOR) of the sample to determine the presence or absence of spores. A detector is also disclosed.

Abstract: A spectroscopic detection device including: a stop in which an aperture is formed; a first and second photodetectors which detect detection light; a collimator which converts the detection light emitted from the stop into substantially parallel light, and emits light to at least one of the first and second photodetectors; a dispersive element which is arranged between the collimator and the first photodetector, and disperses the detection light; a condensing optical system which condenses the detection light dispersed by the dispersive element to the first photodetector; and a wavelength selection filter which is arranged between the collimator and the second photodetector, and allows light in a specified wavelength range to enter the second photodetector. The collimator is configured so that the focal distance for the detection light emitted to the first photodetector may be different from the focal distance for the detection light emitted to the second photodetector.

Abstract: Disclosed herein are methods and devices for evaluating the optical properties of a turbid medium, wherein the medium is one which both absorbs and scatters light. Turbid media of particular interest include fluids such as coolants, paints, etc., and biologically or medically relevant fluids, such as blood, culture media, etc. The methods and devices disclosed herein can also be used to measure changes in optical properties of a tissue (e.g., an epithelial layer) that are associated with a variety of disease states. Changes or differences in the optical properties of tissue can provide indicia of a pathological state or the efficacy of a therapeutic regimen. In general, the change or difference can be a change or difference relative to a standard that is either internal or external. Also disclosed herein are methods for obtaining absolute values for optical properties that are generally obtained as relative values.

Abstract: An apparatus measuring optical characteristics including position detection is disclosed. A processor is coupled to a display. A first optical sensor makes a first measurement, and a second optical sensor makes a second measurement. A source of illumination and the first optical sensor determine a minimal distance between the apparatus and an external object such that illumination emitted by the source is not received by the first optical sensor when the apparatus is less than the minimal distance from the external object. A position of the apparatus with respect to an object and an optical property of light received by the apparatus are determined. A transparent member with a thickness less than the minimal distance may provide illumination external to the apparatus and receive light from external to the apparatus.

Abstract: A method for measuring optical properties of an optically variable marking applied on an object, the method including the steps of illuminating the optically variable marking so as to form a first light reflected by the marking at a first view angle and a second light reflected by the marking at a second view angle, the first and second lights having different spectral compositions as a result of the optically variable marking, refracting the second reflected light through a optical unit so as to redirect the second reflected light toward an optical sensor, capturing the first light and the second refracted light with the optical sensor simultaneously; and determining optical properties of the optical variable marking based on the captured first and second lights.

Abstract: A system includes a first sensor unit having multiple solid-state light sources each configured to generate light at one or more wavelengths, where different light sources are configured to generate light at different wavelengths. The first sensor unit also includes a mixer configured to mix the light from the light sources and to provide the mixed light to a web being sampled. The first sensor unit further includes a controller configured to control the generation of the light by the light sources. The system also includes a second sensor unit comprising a detector configured to measure mixed light that has interacted with the web. The second sensor unit could also include a second controller configured to determine one or more characteristics of the web (such as moisture content and fiber weight) using measurements from the detector.

Abstract: A multimodal method for imaging tissue comprising: aligning an excitation light source with at least a portion of the tissue; selecting at least two modalities of image acquisition; imaging the tissue portion with each of the modalities of image acquisition; and constructing a dual mode image using images from each of the modalities of image acquisition. A multimodal system for imaging tissue comprising: an excitation light source or light sources; an optical and alignment system for directing the excitation beam or beams to a sample and receiving an emission beam from the sample; at least one detector for receiving the emission beam from the sample; and a spectral filtering or dispersing device for providing at least two imaging modalities at the at least one detector; and a processor for analyzing the detected emission beam and constructing a dual mode image using images from each of the modalities of image acquisition.

Abstract: A sensor system for remote object detection, tracking, characterization, and discrimination can have a plurality of sensors. A shared optical train that can facilitate blending of information from the sensors, so as to provide a single view for the plurality of sensors. Small and/or dim objects can be more readily detected. High-resolution 3 dimensional space object imagery and on-demand target information gathering can be provided with reduced data latency. The undesirable effects of atmospheric turbulence along the aiming direction can be mitigated even when there is a high relative velocity between the surveillance platform and remote target.

Abstract: This invention is directed to extract the scattering characteristic of a measurement target together when measuring the surface shape in a measurement system, which measures the surface shape of a measurement target, by the pattern projection method. To accomplish this, the measurement system includes an illumination unit which irradiates a measurement target with dot pattern light, a reflected light measurement unit which receives the reflected light at a reflection angle almost equal to a incident angle, and a reflected light extraction unit which extracts the inclination of the surface of the measurement target, based on the shift amount between the light receiving position of the received reflected light and a predetermined reference position, and extracts the luminance value of the reflected light and the dot diameter of the dot pattern light as information about the scattering characteristic.

Abstract: A monitoring system and associated operational method are operatively configured with a wind turbine for detecting separation of shell members along an edge of a wind turbine rotor blade. The system includes any configuration of sensors disposed within an internal cavity of the rotor blade, with the sensor oriented relative to a leading or trailing edge of the blade and configured to detect a physical characteristic within the blade that is indicative of onset of a separation between the shell members along the monitored edge. A controller is configured to receive signals from the sensor and to initiate an automatic response to a detected separation.

Abstract: Disclosed is an optical constant measuring method which includes applying light to a sample including a target material; measuring a first optical signal from light reflected from the sample; grasping a structure of the sample based on the first optical signal; measuring a second optical signal from light penetrating the sample; grasping an overall optical property of the sample based on the second optical signal; and measuring an optical constant of the target material based on the measured structure and optical property of the sample.

Abstract: There is provided an optical rotation measurement apparatus and a measuring system which are user-friendly, capable of measuring glucose concentration in drawn blood and living bodies with high accuracy in real time such that it is available for use at an actual medical site without depending on a reagent, and capable of measuring glucose concentration in a living body noninvasively with high accuracy, a new polarized light converting optical system that can be used for the measuring system, and an optical rotation measurement method using the optical system.

Abstract: A system and method for non-contact specimen container characterization includes a processor, and a specimen container diameter sensor, and a specimen container length sensor. The non-contact specimen container can also include a cap color sensor. The sensors are located in a fixed position relative to a conveyor for transporting a plurality of specimen containers. Another embodiment is directed to a system and method for detecting centrifuge imbalance along multiple axes. First, second and third comparators compare an accelerometer output corresponding to x-, y- and z-axes with reference voltage levels. The outputs are used to determine whether to discontinue operation of the centrifuge. The outputs can also be used to generate alerts.

Abstract: The present disclosure provides for a system and method for detecting unknown materials. A test data set, which may comprise a hyperspectral data set, is generated representative of a first location. The test data set may be analyzed to determine a second location which may be interrogated using a Raman spectrocscopic device to generate a Raman data set. The Raman data set may be analyzed to associated an unknown material with a known material such as: a chemical material, a biological material, an explosive material, a hazardous material, a drug material, and combinations thereof.

Abstract: An inspecting method and apparatus for inspecting a substrate surface includes illuminating a light to the substrate surface having a film, detection of a scattered light or reflected light from a plurality of positions of the substrate surface to obtain a plurality of electrical signals, comparison of the plurality of electrical signals and a database which indicates a relationship between the electrical signals and surface roughness, and calculation of a surface roughness value based on the result of comparison.

Abstract: The optical system of the preferred embodiments includes a first light source that creates a first beam of a first wavelength, a first collimating element that collimates the first beam, a second light source 102 that creates a second beam of a second wavelength, a second collimating element that collimates the second beam, a beam combining element that combines the collimated beams, and a focusing element that focuses the combined collimated beam to a single point.

Abstract: Smart fiber optic sensors, systems, and methods for performing quantitative optical spectroscopy are disclosed. In one embodiment, smart fiber optic sensor can include a sensing channel, a calibration channel, and a pressure sensing channel. External force or pressure can be calculated at pressure sensing channel for monitoring and controlling pressure at a sensor-specimen interface thereby ensuring more accurate specimen spectral data is collected. Contact pressure can be adjusted to remain within a specified range. A calibration light of the calibration channel and an illumination light of the sensing channel can be generated simultaneously from a shared light source. Pressure sensing channel can transmit light from a second light source and collect pressure spectral data.

Abstract: A method for determining the surface topography of a coated object and for the simultaneous spatially resolved determination of the thickness of the layer on the coated object. It is provided that the surface topography is measured with the aid of white-light interferometry, the thickness of the layer is measured by the principle of reflectometry, and by using, for both measurements, a shared radiation source having an electromagnetic radiation spectrum, which is reflected from the layer surface in a first wavelength range contained in the radiation spectrum and which penetrates into the layer in a second wavelength range contained in the radiation spectrum. Also described is a corresponding optical measuring instrument. The method and the optical measuring instrument make simultaneous highly accurate surface measurement of the surface topography and of the layer thickness of coated objects possible.

Abstract: A mobile storage having a mobile storage unit having a detection side; an opposing component having an aisle side facing the detection side; the mobile storage unit being movable between a closed position and an open position wherein an aisle is defined; at least one detection module having an optical pulse emitter and an optical detector both provided at an end, facing the aisle, the optical pulse emitter emitting a light pulse, the optical detector detecting a reflection of the light pulse. An object detection method for a mobile storage comprising comparing a temporal reflection signal to a background temporal reflection signal to detect the presence of an object; and indicating a status of the aisle to be presence of an object if the object is detected to be present.

Abstract: Devices, systems and methods facilitate analyzing, identifying and sorting particles in fluids, including cytometry devices and techniques. The described techniques can be used in a variety of applications such as in chemical or biological testing and diagnostic measurements. One exemplary flow cytometry device includes a channel that is capable of conducting a fluid containing at least one particle and also capable of allowing light be transmitted to and from the channel. The flow cytometry device also includes a lens that is positioned between the channel and a color filter. The lens directs at least a portion of light transmitted from the channel to the color filter. The color filter includes a plurality of zones, where each zone is adapted to allow transmission of only a particular spectral range of light. The flow cytometry device further includes a detector configured to receive the light that is transmitted through the color filter.

Abstract: Brightness factors associated with shade fabric may be utilized when shading a building. A brightness factor may incorporate an openness factor, a visible light reflectance, a diffusion factor, a color, or other characteristics of the shade fabric. The brightness factor may be utilized when selecting a particular shade fabric for a room, building or other location. Additionally, the brightness factor may be utilized by an automated shade control system. The shade fabric selection may affect the building envelope by facilitating the optimization of daylighting, reduction of artificial electric lighting needs, minimization of glare conditions, and reduction of thermal load.

Abstract: A for traceably determining an unknown optical path length of a sample in an optical measuring device comprises the steps of: providing a drop analyser connected to a standard spectrophotometer; providing a certified reference material contained in first and second closed high accuracy cuvettes; measuring absorbance of the certified reference material to obtain a first absorbance measurement for the first specified path length; measuring absorbance of the certified reference material for a second path length to obtain a second absorbance measurement; using a dropping device to drop a specified volume of the solvent on an optical surface so that the path length of the specified volume can be determined by reference to the first and second absorbance measurement; and using the dropping device to drop the same volume of sample as the specified volume of solvent on the optical measuring device.