Abstract: The present describes a system and method for determining the concentration of tetrahydrocannabinol (THC) including a tray comprising a first analyte including an infusion of a solvent and cannabis, a light emitting element configured to illuminate the first analyte, a light receiving element configured to receive a first light transmitted through the first analyte, and a control circuit configured to calculate a concentration of tetrahydrocannabinol in the first analyte based at least in part on the first light.

Abstract: The present invention provides a novel simple, portable, compact and inexpensive approach for interferometric optical thickness measurements that can be easily incorporated into an existing microscope (or other imaging systems) with existing cameras. According to the invention, the interferometric device provides a substantially stable, easy to align common path interferometric geometry, while eliminating a need for controllably changing the optical path of the beam. To this end, the inexpensive and easy to align interferometric device of the invention is configured such that it applies the principles of the interferometric measurements to a sample beam only, being a single input into the interferometric device.

Abstract: According to one embodiment, in a measurement apparatus, a controller acquires a first signal waveform, a second signal waveform, and a third signal waveform. Among mth diffraction light and ±nth diffraction light, the first signal waveform is related to spatial distribution of light intensity about first interference light by interference of the ±nth diffraction light. The second signal waveform is related to spatial distribution of light intensity about second interference light by interference of the mth diffraction light and the +nth diffraction light. The third signal waveform is related to spatial distribution of light intensity about third interference light by interference of the mth diffraction light and the ?nth diffraction light. The controller calculates a measurement error component based on a phase difference between the second signal waveform and the third signal waveform. The controller corrects the first signal waveform with using the calculated measurement error component.

Abstract: A semiconductor measuring tool has a folding mirror configuration that directs a light beam to pass the same space multiple times to reduce the size and footprint. Furthermore, the folding mirrors may reflect the light beam at less than forty-five degrees; thereby allowing for smaller folding mirrors as compared to the prior art.

Abstract: According to an embodiment of the invention, an apparatus to detect fluorescence from a sample is disclosed. The apparatus comprises a sample plane onto which the sample is arranged, an excitation light unit including at least a light source to illuminate the sample, and a detection unit comprising at least a detector having at least 100,000 active detection elements to detect a fluorescence signal from the sample.

Abstract: A measurement system performs non-destructive quality control or constitutive analysis using a light source generating an output optical beam using semiconductor sources that generate an input optical beam, a multiplexer configured to receive the input beam and to form an intermediate optical beam, and fibers configured to receive the intermediate beam and to form the output beam. The fibers include a fused silica fiber having a core diameter less than 400 microns. The output beam includes wavelengths between 700 and 2500 nanometers and has a bandwidth of at least 10 nanometers. The system includes a measurement apparatus that receives the output beam and delivers the beam to a sample to generate a spectroscopy beam. A receiver is configured to receive the spectroscopy beam and process the beam to generate an output signal. The light source and receiver are remote from the sample, which includes plastics or food industry goods.

Abstract: A method of fabricating a gas sensor on a substrate and a gas sensor fabricated on a substrate that includes optical and electronic components are described. The method includes fabricating a laser to output light over a range of wavelengths within a waveguide, fabricating a splitter to split the light output by the laser to a reference waveguide and to a detection waveguide, fabricating a reference cell to house the reference waveguide and a reference gas. An output of the reference waveguide is coupled to a first optical detector and an output of the detection waveguide is coupled to a second optical detector to identify or quantify an ambient gas.

Abstract: Systems, apparatuses and methods may provide for a light collector to capture an inbound optical signal and a plurality of detectors, wherein each detector is associated with a wavelength detection range that differs from one or more wavelength detection ranges associated with one or more remaining detectors in the plurality of detectors. Additionally, a microelectromechanical system (MEMS) device may include a plurality of mirrored columns, wherein each mirrored column is coated with a material that is associated with a wavelength reflection range that differs from one or more wavelength reflection ranges associated with one or more remaining mirrored columns in the plurality of mirrored columns. In one example, the MEMS device positions the plurality of mirrored columns to route the inbound optical signal to one or more of the plurality of detectors based on an input signal from a user input device.

Abstract: The invention provides a method and system to record the absorption of a sample, said method comprising the steps of providing first and second pulsed beam of light on said sample using one or more light beams, said first and second pulsed beam having different spatial definition; measuring the difference in intensity transmitted through and/or reflected by a sample; and generating an image by scanning the sample while making such measurements. The system and method of the invention can work down to resolution of several 100 of nm, affording thus a large improvement in comparison to synchrotron IR imaging that is the closest technique existing today. The advantage versus scanning probe approach is the absence of physical probe, thus suppressing confinement to surface information and removing uncertainty regarding the working behavior of the probe.

Abstract: An integrated receiver supports adaptive receive equalization. An incoming bit stream is sampled using edge and data clock signals derived from a reference clock signal. A phase detector determines whether the edge and data clock signals are in phase with the incoming data, while some clock recovery circuitry adjusts the edge and data clock signals as required to match their phases to the incoming data. The receiver employs the edge and data samples used to recover the edge and data clock signals to note the locations of zero crossings for one or more selected data patterns. The pattern or patterns may be selected from among those apt to produce the greatest timing error. Equalization settings may then be adjusted to align the zero crossings of the selected data patterns with the recovered edge clock signal.

Abstract: The invention provides a method and apparatus for improving throughput in spectrometry, the method comprising the steps of loading sample-containing liquid into a liquid injection device through a first outlet in the injection device, and ejecting at least some of the sample-containing liquid from the liquid injection device either in the form of droplets or in the form of a jet which subsequently breaks up into droplets due to instability; characterized by the sample ejection being through the first outlet of the liquid injection device in a direction such that the sample-containing fluid enters an inlet of a torch.

Abstract: A system to generate multiple beam lines in an oblique angle multi-beam spot scanning wafer inspection system includes a beam scanning device configured to scan a beam of illumination, an objective lens oriented at an oblique angle relative to the surface of a sample and with an optical axis perpendicular to a first scanning direction on the sample, and one or more optical elements positioned between the objective lens and the beam scanning device. The one or more optical elements split the beam into two or more offset beams such that the two or more offset beams are separated in a least a second direction perpendicular to the first direction. The one or more optical elements further modify the phase characteristics of the two or more offset beams such that the two or more offset beams are simultaneously in focus on the sample during a scan.

Abstract: A system for measuring soil constituents having coulter comprising an electromagnetic radiation detector, a source of electromagnetic radiation, and a window transparent to electromagnetic radiation, the source emits radiation through said window to the soil, and the detector receives radiation through said window, reflected from the soil. Typically the source is broad band so the detector provides continuous spectra over the range. The source may be quasimonochromatic to provide Raman scattering, which will also provide continuous spectra over the range. These spectra can be subjected to multivariate analysis and compared to spectra of known constituents to identify the presence and concentration of these constituents.

Abstract: A wearable device for use with a smart phone or tablet includes a measurement device having a light source with a plurality of light emitting diodes (LEDs) for measuring physiological parameters and configured to generate an optical beam with wavelengths including a near-infrared wavelength between 700 and 2500 nanometers. The measurement device includes lenses configured to deliver the optical beam to a sample of skin or tissue, which reflects the optical beam to a receiver located a first distance from one of the LEDs and a different distance from another of the LEDs, and is also configured to generate an output signal representing a non-invasive measurement on blood contained within the sample. The wearable device is configured to communicate with the smart phone or tablet, which receives, processes, stores and displays the output signal with the processed output signal configured to be transmitted over a wireless transmission link.

Abstract: A probe including reflector is disclosed to measure the velocity distribution of a moving surface along many lines of sight. Laser light, directed to the surface by the probe and then reflected back from the surface, is Doppler shifted by the moving surface, collected into probe, and then directed to detection equipment through optic fibers. The received light is mixed with reference laser light and using photonic Doppler velocimetry, a continuous time record of the surface movement is obtained. An array of single-mode optical fibers provides an optic signal to one or more lens groups and a reflector, such as a parabolic reflector having a mirrored interior surface.

Abstract: An instrument has a light-emitting and light-receiving assembly including an image capture unit and image processing unit; a backscatterer and an opening provided therein; a support for receiving an ophthalmic lens between the assembly and backscatterer, the assembly, support and backscatterer placed so that an incident light beam traverses the lens, strikes the backscatterer, returns and re-traverses the lens to arrive at the capture unit; the light-receiving assembly, the support, backscatterer and opening configured so that the assembly receives light from the beam; and the opening and a drive device for cyclically driving and making the backscatterer perform an identical movement in each cycle, configured so that a fixed zone opposite the backscatterer includes at least one part of which, over the course of a cycle, every point is at times perpendicular to the opening and at times perpendicular to a solid portion part of the backscatterer.

Abstract: A lightpipe is coupled to a spectrometer based on a laterally variable optical filter. The lightpipe may be used for both guiding the illuminating light towards a sample and collecting light reflected or emitted by the sample upon illumination, for spectral measurements at a distance from the sample afforded by the lightpipe. The lightpipe may include a slab of homogeneous transparent material for unconstrained bidirectional propagation of light in bulk of the material. The lightpipe may be solid, hollow, or sectioned for separate guiding of the illuminating and the reflected light.

Abstract: A dual-frequency grating interferometer displacement measurement system, comprises a dual-frequency laser, an interferometer, a measurement grating and an electronic signal processing component. The measurement system realizes displacement measurement based on grating diffraction, optical Doppler effect and optical beat frequency theory. Dual-frequency laser light is emitted from the dual-frequency laser and split into reference light and measurement light via a polarization spectroscope. The measurement light is incident to the measurement grating to generate positive and negative first-order diffraction. The diffraction light and the reference light form a beat frequency signal containing displacement information about two directions at a photo-detection unit, and linear displacement output is realized after signal processing.

Abstract: A particle measuring apparatus according to an embodiment includes a first supply part that introduces first gas. A second supply part introduces second gas having been filtered. A light source irradiates mixture gas including the first gas and the second gas with light. A light detector detects reflected light from the mixture gas and measures number of particles contained in the mixture gas. A pump sucks the mixture gas.

Abstract: A method for analyzing a light emission of a headlight of a vehicle includes: a step of reading in a distance which represents a distance between the vehicle and an object situated in the surroundings of the vehicle; a step of reading in an illumination value which represents a height of an area of the object which is illuminated by the light emission; and a step of determining a light emission value which characterizes the light emission, using the distance value and the illumination value.