Abstract: In some embodiments, at least one processor determines a range of search directions to a suspected gas leak source by receiving data representative of a plurality of wind direction measurements relative to a geo-referenced location of at least one gas concentration measurement point. The range of search directions extending from the location of the gas concentration measurement point is calculated according to a variability of the wind direction measurements.

Abstract: A method for testing the tightness of a housing involves providing a pressure sensor in a housing, sealing the housing, and detecting a pressure level in the housing.

Abstract: A device receives information, associated with civil structures, that includes temperature information associated with the civil structures, pressure information associated with the civil structures, stress information associated with the civil structures, vibration information associated with the civil structures, or displacement information associated with the civil structures. The device performs an analysis of the information associated with the civil structures via one or more analytics techniques, and generates analysis information based on the analysis of the information associated with the civil structures. The analysis information identifies a potential issue with at least one of the civil structures, and the device provides the analysis information for display.

Abstract: This optical system includes: a device (106) for generating a plane light wave, called a collimated light wave (OLcol); and a device (114) for deviating the collimated light wave so as to provide a light wave, called a test light wave (OLtest), the deviating device (114) having an adjustable focal length.

Abstract: The disclosed technology includes, among others, methods and devices for measuring distributed fiber bend or stress related characteristics along an optical path of fiber under test (FUT) uses both a light input unit and a light output unit connected to the FUT at one single end.

Abstract: A gas sensor includes a gas sensing element positioned at least partially within a body and being exposed at a first end to measure a gas in contact with the first end. A sleeve is fixed to the body and extends from the body in a direction opposite the first end of the gas sensing element. The sleeve includes it remote end portion having an engagement feature. A connector housing is overmolded onto the end portion of the sleeve to lock onto the sleeve via the engagement feature. The connector housing includes a plug connector portion partially enclosing a plurality of electrical terminals electrically connected to the gas sensing element.

Abstract: The present invention relates to a test arrangement for the crash simulation of motor vehicles, said test arrangement having a first carriage, which is movable substantially horizontally along a longitudinal axis, and a second carriage, which is movable along the longitudinal axis together with the first carriage, wherein the second carriage is attached to the first carriage in such an articulated manner that the second carriage is movable with respect to the first carriage. In order to be able to simulate actual accident conditions better, in the test arrangement according to the invention, in addition to at least one first actuating element and at least one second actuating element, there is also provided at least one third actuating element, which is configured to accelerate the second carriage in a horizontal direction substantially perpendicular to the longitudinal axis.

Abstract: A tire wear state estimation system for a tire calculates tire effective radius during measured distance intervals travelled by the tire from vehicle speed and tire rotation counters. The system includes a filter for selecting slow-speed effective radius measuring intervals and an estimator for estimating the tire effective radius during only those intervals in which the vehicle is travelling below a threshold speed.

Abstract: A field device commissioning system includes a commissioning tool, which is configured to communicate with a field device and a repository. The commissioning tool is configured to retrieve at least one property from a field device. The commissioning tool is configured to determine, from a registration file in the repository, if the retrieved at least one property is in the registration file. When the retrieved at least one property is determined to be in the registration file, perform a first test. When the retrieved at least one property is determined to be not in the registration file, determine, from a control system loop information file in the repository, if the retrieved at least one property is for a predetermined field device. When the retrieved at least one property is determined to be for the predetermined device, perform a second test different from the first test.

Abstract: Apparatus for a cotton sample acquisition and tracking system. The system includes a loading station in which a pair of primary sample halves are loaded in a carrier. The primary samples are identified and transported to a sub-sample station that extracts a sub-sample from the primary sample. The sub-samples are conditioned and transported to various testing stations. The primary samples are transported via a conveyor system. The sub-samples are transported through a pneumatic system. The sub-sample station advances the primary sample against a pick drum that pulls tufts from the primary sample. The tufts flow through a cotton containment system into an indexer that collects, conditions, and routes the tufts as a sub-sample. The sub-samples are staged in a carousel for continued conditioning and storage until the test equipment is ready to process the sub-sample.

Abstract: Provided is a process of using a microtomic system for the preparation of sections for microscope examination. A cutting edge in the system can cut through a sample block and produce a section one end of which remains attached to the cutting edge. A voltage generator can generate a voltage and apply the voltage between the cutting edge and a section receiver such as a semiconductor chip grid. Through electrostatic force caused by the voltage, another end of the section can anchor to the section receiver. The section is then spread on the receiver. The system is automatable, highly efficient, and does not need liquid to float sample sections, and can therefore maintain the integration of the sample sections.

Abstract: The current invention describes in vivo and vitro (cultured) sampling technologies that allow direct temporal and spatial sampling from living ecosystems such as those associated with marine ecology. The optional use of parallel sampling methods, observatory design, provides for the ability to measure the response of individual organisms to a variety of both biotic and abiotic stresses. Sampling in small volumes and close proximity to living organisms has allowed direct measurement of various invertebrate and other aquatic species in marine ecosystems. These sampling techniques are intended to apply to any liquid based ecosystem in an attempt to minimize sampling as a dependent variable in measuring the chemical and biological behavior of the ecosystem. If is intended that this sampling technology be used to directly measure the chemical behavior of a wide variety of organisms; including, plants, animals, and micro-organisms (e.g. algae, plankton).

Abstract: An exemplary embodiment of the present invention provides a simultaneous multipoint testing system for analyzing the composition of a fluid in a duct. The system can comprise a plurality of probes each having a plurality of sample legs at different locations within the duct. Each probe can also comprise a mixing chamber for mixing fluid samples collected by each of the sample legs. The system can further comprise a global mixing chamber configured to receive the mixtures of fluid samples from each probe mixing chamber and mix those fluid samples to create a global fluid sample. The system can further comprise an analyzer configured to receive at least a portion of the global fluid sample and measure levels predetermined compounds present in the at least a portion of the global fluid sample.

Abstract: A sample processing device includes a receiving chamber having a chamber inlet and a chamber outlet. The processing device also includes a metering portion having a metering reservoir fluidly coupled to the chamber outlet, and at least one vessel fluidly coupled to the metering reservoir by a syphon. The syphon is operable to actuate upon a preselected volume of liquid being received at the metering reservoir. The syphon includes a syphon inlet and a syphon outlet, with the syphon outlet being fluidly coupled to the vessel. The preselected volume of liquid corresponds to a volume of liquid necessary to deliver a metered volume of fluid to the vessel.

Abstract: The invention relates to methods of extracting DNA from seeds, said method comprising pretreating said seeds by soaking the seeds in a pretreatment solution comprising an alkali in a concentration sufficient to soften said seed; crushing said seeds; extracting said DNA from said crushed seeds. Methods also relate to the use of pretreatment solutions which further comprise an osmoticum. A method of fragmenting plant material such as seed, a method of recovering extraction medium from seed fragmentation and a process of extracting a seed component from crushed seed material are also described.

Abstract: A laser microdissectate specimen collector for a laser microdissection device includes a collecting chamber configured to receive a dissectate. The collecting chamber has, on a specimen side, an opening open to the environment for receiving the dissectate. The collecting chamber also has a first valve. The first valve, in a closed state thereof, forms a closure of the collecting chamber opposite to the opening for retaining the dissectate. A capillary line is connected downstream of the first valve to the collecting chamber such that the capillary line is configured to transport the dissectate out of the collecting chamber.

Abstract: Contemplated herein is an automated microscope slide antigen recovery and staining apparatus and method that features a plurality of individually operable miniaturized pressurizable reaction compartments for individually and independently processing a plurality of individual microscope slides. The apparatus preferably features independently movable slide support elements each having an individually heatable heating plate. Each slide support element may support a microscope slide. Each microscope slide can be enclosed within an individual pressurizable reaction compartment. Pressures exceeding 1 atm or below 1 atm can be created and maintained in the reaction compartment prior to, during or after heating of the slide begins.

Abstract: A liquid filling aid that is placed on a plate-shaped member and defines a reaction chamber to be filled with a liquid, the aid includes a main body, a storage section that is formed in the main body and stores the liquid, a reaction section that is a recess formed at a bottom of the main body, a communication aperture for fluid communication between the storage section and the reaction section, and an air vent for communication between the reaction section and outside air, wherein the reaction section and an upper surface of the plate-shaped member define the reaction chamber and a liquid filling method including a step of placing the liquid filling aid on the plate-shaped member, and a step of discharging the liquid in an amount equal to or larger than the volume of the reaction chamber for supply to the storage section.

Abstract: A system and method for mounting a section onto a substrate, the system comprising: a fluid channel including: a fluid channel inlet that receives the section, processed from a bulk embedded sample by a sample sectioning module positioned proximal the fluid channel inlet, a section-mounting region downstream of the fluid channel inlet, and a fluid channel outlet downstream of the section-mounting region; a reservoir in fluid communication with the fluid channel outlet; and a manifold, fluidly coupled to the reservoir, that delivers fluid from the reservoir to the fluid channel inlet, thereby transmitting fluid flow that drives delivery of the section from the fluid channel inlet toward the section-mounting region.

Abstract: A device and method for testing a fiber-composite component, which is to be processed by means of bonding, for the presence of at least one substance out of a selection of possible contaminants. A surface heating device for regional heating of a part-zone of the fiber-composite component to be bonded is performed for desorption of contaminants. A sensor array with a plurality of sensors detects contaminants in the gas phase, and a control device ascertains and signals contaminations which are found. An extractor device can be employed to extract machining dust from the fiber-composite component to a desorption device.

Abstract: A system and method for verifying the operational condition of a rectangular baler having a baling chamber equipped with a reciprocating plunger, the plunger moving between a fully retracted position and extended position, the baler further equipped with a load sensor suitable for determining the reaction force on the plunger as said plunger is compressing crops.

Abstract: This invention installs multiple miniature strain gauges inside a regular dimensioned bolt washer to accurately measure bolt preload. To enhance the strain gauge sensitivity, an alloy with low elastic modulus and high yield strength is selected to fabricate the metal washer. In addition, multiple gauges are connected in series to multiply the effective gauge length and enhance measurement sensitivity. Further, the stain gauges are encapsulated in the middle of the washer as opposed to on the external surface which offers much improved sensitivity and physical protection of the strain gauges.

Abstract: Systems and methods for testing an impact response of a material and/or structure to one or more impacts of known magnitude. The systems and methods include a portable impactor device for imparting an impact force on a surface of an engineered structure, wherein the portable impactor device has an adjustable orientation such that an impact may be delivered as an angle ranging from +90° to ?90° relative to a horizontal plane. Additionally, the portable impactor device described may be utilized to test an impact response of one or more surface areas of a full-scale prototype structure.

Abstract: A helmet testing apparatus including a movable member, a sensor coupled to the movable member and configured to acquire compliance data regarding a liner disposed within a shell of a helmet through engagement of the sensor with the liner, and a processing circuit configured to determine a rating for the helmet based on the compliance data and predetermined compliance parameters for the helmet.

Abstract: The penetrometer includes a chassis, a mast mounted thereon and positioned substantially vertically during a test, a rod string, including a tip penetrating the ground that is positioned at one end of the rod string, an anvil that bears against the rod string at an end opposite the tip, a hammer striking the anvil, elements for raising the hammer along the mast up to a fall height, at which the hammer is released, and elements for measuring the sinking of the tip into the ground. The penetrometer further includes an electronic control unit for controlling the fall height, and configured to select the fall height adopted for the test based on the sinking of the tip measured by the measuring elements during one or more earlier tests, and mechanical elements controlled by the control unit for triggering the fall of the hammer at the height selected by the control unit.

Abstract: A density and viscosity sensor for measuring density and viscosity of a fluid, comprises: a housing (4) defining a chamber (8) isolated from the fluid (3), the housing (4) comprising an area defining a membrane (9) separating the chamber (8) from the fluid (3); a resonating element (5) arranged to be immersed in the fluid (3) and mechanically coupled to the membrane (9); and an actuating/detecting element (6) coupled to the resonating element (5), the actuating/detecting element (6) being positioned within the chamber (8) and mechanically coupled to the membrane (9), the actuating/detecting element (6) comprising at least one piezoelectric element (10) comprising two sides (11, 12) substantially parallel to the membrane (9); The membrane (9) has a thickness enabling transfer of mechanical vibration between the actuating/detecting element (6) and the resonating element (5). One side (11) of the piezoelectric element (10) comprises a single conductive area (13).

Abstract: Provided is a method for non-destructively measuring an electrode density and an electrode porosity of an electrode active material coated on an electrode base material using X-ray diffraction. According to the methods of the present invention, a value of Ipeak in parallel direction/Ipeak in perpendicular direction of the electrode active material is obtained by X-ray diffraction and an electrode density and an electrode porosity are calculated according to previously obtained correlations between the electrode density and Ipeak in parallel direction/Ipeak in perpendicular direction and between the electrode porosity and Ipeak in parallel direction/Ipeak in perpendicular direction.

Abstract: A method for determining a condition in a blood sample includes: providing a sample of blood; providing a metering probe having a pump for aspirating and dispensing; inserting the metering probe a selected distance into the blood sample; measuring the pressure between the sample and pump during sample aspiration or sample dispense; comparing the measured pressure with a reference value; and signaling the presence or absence of the condition. A method for confirming or detecting the presence of a selected layer of blood component in a centrifuged blood sample includes: measuring a pressure of a suspected selected layer in a metering probe during aspiration or dispense; comparing the measured pressure with a reference value, wherein if the measured pressure and the reference value are substantially identical then the selected layer of the blood component is confirmed. In a preferred embodiment the reference value is a pre-selected pressure range.

Abstract: A particulate detection system (1) for detecting the quantity of particulates S in a gas under measurement EG, including a detection section (10), a drive circuit (210, 240), and a control section (230, 202). The detection section (10) has an ion source (11) and a particulate electrification section (12). The drive circuit (210) includes an ion source drive circuit (210) for performing constant current control. The control section (230, 202) includes current convergence determination means S2-S3, S5-S6, and detection start means S8 for starting detection of the quantity of the particulates S using the signal Is, detected by a detection circuit (230), after the gaseous discharge current Id has converged to an allowable range IR.

Abstract: A device for electrofracturing a material sample and analyzing the material sample is disclosed. The device simulates an in situ electrofracturing environment so as to obtain electrofractured material characteristics representative of field applications while allowing permeability testing of the fractured sample under in situ conditions.

Abstract: An apparatus and method for measuring molecular diffusivity in porous powders or minerals, e.g., the microporous synthetic minerals used for gas separation and chemical catalysis, were invented that allows a varying pressure in the gas around the powder during the measurement. This obviates the need for the pressure to be constant and the attendant complicated component parts. A mass balance model equation of the sample cell with the diffusivity as an adjustable parameter is used to deduce the sample cell pressure change versus time (uptake curve) until the equilibration of gas diffusion into the powder. A numerical analysis method is used to solve the mathematical model to compute a simulated uptake curve. Curve fitting of the simulated and measured uptake curves is used to optimize the diffusivity parameter, which gives the measured diffusivity. The apparatus and method are simple, easy to use, and automation is also simple.

Abstract: A particle detecting device includes: a chamber; an injection nozzle provided within the chamber; a discharge nozzle that is disposed within the chamber, opposing the injection nozzle; a detecting mechanism that illuminates a sample fluid that is sprayed from the injection nozzle and detects a particle included in the sample fluid; a pressurizing fluid pipe, connected to the chamber, for supplying a pressurizing fluid for pressurizing an interior of the chamber; and a rectifying member that rectifies the pressurizing fluid so that a flow speed distribution of a fluid between the injection nozzle and the discharge nozzle, rectified in an axial direction, is symmetrical in respect to the axial direction.

Abstract: An in-line holographic microscope can be used to analyze on a frame-by-frame basis a video stream to track individual colloidal particles' three-dimensional motions. The system and method can provide real time nanometer resolution, and simultaneously measure particle sizes and refractive indexes. Through a combination of applying a combination of Lorenz-Mie analysis with selected hardware and software methods, this analysis can be carried out in near real time. An efficient particle identification methodology automates initial position estimation with sufficient accuracy to enable unattended holographic tracking and characterization.

Abstract: A cross-cut tester includes a handle with a receiving cavity, and a plurality of blades received in the receiving cavity. One end of the handle defines an opening. The cross-cut tester further includes a plurality of gaskets received in the receiving cavity. The gaskets and the blades are positioned one-by-one, and are detachably fixed in the receiving cavity. The cross-cut tester of the present disclosure can effectively improve the efficiency of drawing lines and reduce the cost.

Abstract: An outer part for a device which is attachable thereto as a housing and/or an attachment part, a first reflective surface and a second reflective surface being formed on the outer part so that at least one signal emitted by an optical and/or acoustic source is directly or indirectly deflectable onto at least one detector surface of an optical and/or acoustic detector, an optical path being configured as a cavern or continuous recess in the outer part or as a depression of a boundary surface of the outer part, the optical path having at least one opening via which at least one substance is transferable into the optical path, and the at least one signal being deflectable into the optical path to the second reflective surface which is formed at a second end of the optical path with the first reflective surface at a first end of the optical path.

Abstract: An embodiment provides a method, including: operating a motor to position sample fluid within a fluid channel of a cuvette; transmitting light through an optical chamber of the cuvette; measuring a value of received light that has been transmitted through the optical chamber; comparing the measured value of light to one or more thresholds; determining a position of the sample fluid within the fluid channel based on a comparison from the comparing step; and generating a response based upon the position of the sample fluid with the fluid channel. Other aspects are described and claimed.

Abstract: A cap for a gas sensor module is described herein. The cap can include at least one wall forming a cavity having a first portion and a second portion. The cap can also include an inlet tube coupling feature disposed in the at least one wall, where the first location is adjacent to the first portion of the cavity. The cap can further include an outlet tube coupling feature disposed in the at least one wall, where the second location is adjacent to the second portion of the cavity. The cap can also include a distribution channel coupling feature disposed in the at least one wall, where the third location is adjacent to the first portion of the cavity. The cap can further include a receiving channel coupling feature disposed in the at least one wall, where the fourth location is adjacent to the second portion of the cavity.

Abstract: An apparatus and method of performing photothermal chemical nanoidentification of a sample includes positioning a tip of a probe at a region of interest of the sample, with the tip-sample separation being less than about 10 nm. Then, IR electromagnetic energy having a selected frequency, ?, is directed towards the tip. Using PFT mode AFM operation, absorption of the energy at the region of interest is identified. calorimetry may also be performed with the photothermal PFT system.

Abstract: The present invention discloses a flow cell optical detection system comprising a light source, a flow cell and a light detector, wherein the light detector is arranged in a separate detector unit that is arranged to be releasably attached to a detector interface, the detector interface being in optical communication with the light source and comprises optical connectors for optically connecting the flow cell and the detector unit in the light path from the light source, and wherein the flow cell is an interchangeable unit arranged to be held in position by the detector unit when attached to the detector interface.

Abstract: An apparatus for determining or monitoring at least one process variable, comprising: a sensor element and a measuring electronics, which form a measuring unit; and at least one control/evaluating/calculating unit arranged removed from the measuring unit; and/or an in/output unit arranged removed from the measuring unit and the control/evaluating/calculating unit. The control/evaluating/calculating unit and the in/output unit are connected with the measuring unit via a first interface and a second interface. The measuring electronics operates the sensor element and forwards the measurement signals via the interfaces to the control/evaluating/calculating unit as unprocessed, raw, measured values. The control/evaluating/calculating unit arranged removed from the measuring unit determines, improves and/or monitors the process variable based on the raw, measured values and makes such available via the in/output unit.

Abstract: An exemplary method for measuring a refractive index of a substance being measured through an optical window, includes arranging the optical window in contact with the substance being measured, directing light to the interface of the optical window and substance being measured, where part of the light is absorbed by the substance being measured and part of it is reflected from the substance being measured to form an image, in which the location of the boundary of light and dark areas expresses a critical angle of the total reflection dependent on the refractive index of the substance being measured, and examining the formed image. Light is directed on a first structure and to desired angles on an interface between the optical window and substance being measured. Light reflected from the interface of the optical window and substance being measured is directed on a second structure.

Abstract: Scatterometry measurement systems, illumination configurations and respective methods are provided, which comprise illumination beams that have vertical projections on a target plane comprising both a parallel component and a perpendicular component, with respect to a target measurement direction. The illumination beams propagate at an angle to the plane defined by the measurement direction and a normal to the targets surface and generate diffraction images which are off-center at the imaging pupil plane. The eccentric diffraction images are spatially arranged to avoid overlaps and to correspond to measurement requirements such as spot sizes, number of required diffraction orders and so forth. The illumination beams may be implemented using illumination pupil masks, which provide a simple way to increase scatterometry measurements throughput.

Abstract: A solid body for adjusting, calibrating and/or function checking of a turbidity sensor, which works with electromagnetic waves, especially light, of at least a first wavelength, and wherein the solid body is transparent at least for the light of the first wavelength, characterized in that at least a first region is provided in the solid body, where at least incident light of the first wavelength is scattered. The scattered light is a measure for turbidity.

Abstract: An optical system comprising: a light source; a photodetector; a first light-receiving system for causing the photodetector to receive first reflected light with a first angle of reflection from a surface; and a second light-receiving system for causing the photodetector to receive second reflected light with a second angle of reflection, different from the first angle of reflection, from the surface is provided. Here, a first light-receiving area of the photodetector with respect to light, of reflected light from the surface, via the first light-receiving system is spaced apart from a second light-receiving area of the photodetector with respect to light, of the reflected light from the surface, via the second light-receiving system.

Abstract: The present invention provides for the surface plasmon-enhancement of long lived luminescent compounds, thereby providing for methods and systems having enhanced and controllable rates of the radiative emission of such relaxation of long lived luminescent compounds. The present invention achieves acceleration of the radiative processes by the interaction of the long lived luminescent compounds with surface plasmons of the metal surfaces.

Abstract: A compact transducer system includes both an antenna subsystem and an optical transducer subsystem. The antenna subsystem may include multiple radio frequency (RF) radiating elements disposed adjacent to a ground plane. The ground plane may also serve as an optical reflector within an optical path of the optical transducer subsystem. A secondary reflector may also be provided within the optical path of the optical transducer subsystem. The secondary reflector may be formed of dielectric material (e.g., meta-material) in some embodiments to prevent undesired coupling with RF circuitry.

Abstract: An apparatus and method are provided for differentiating multiple detectable signals by excitation wavelength. The apparatus can include a light source that can emit respective excitation light wavelengths or wavelength ranges towards a sample in a sample retaining region, for example, in a well. The sample can contain two or more detectable markers, for example, fluorescent dyes, each of which can be capable of generating increased detectable emissions when excited in the presence of a target component. The detectable markers can have excitation wavelength ranges and/or emission wavelength ranges that overlap with the ranges of the other detectable markers. A detector can be arranged for detecting an emission wavelength or wavelength range emitted from a first marker within the overlapping wavelength range of at least one of the other markers.

Abstract: Described herein are microfluidic devices and methods of detecting an analyte in a sample that includes flowing the sample though a microfluidic device, wherein the presence of the analyte is detected directly from the microfluidic device without the use of an external detector at an outlet of the microfluidic device. In a more specific aspect, detection is performed by incorporating functional nanopillars, such as detector nanopillars and/or light source nanopillars, into a microchannel of a microfluidic device.

Abstract: An excitation light source emits excitation light to a target sample. An image sensor includes pixels arranged one-dimensionally or two-dimensionally, and receives measurement light from the sample according to the excitation light. A polarization selector arranged between the sample and image sensor includes pixels arranged one-dimensionally or two-dimensionally. Each pixel receives a corresponding portion of the measurement light, selects light having a polarization direction that corresponds to a driving signal applied to the pixels, and supplies this light to the image sensor. A measurement control unit supplies the cyclic driving signal having a first period T1, and acquires data I1, I2, I3, and I4 from each pixel of the image sensor for each exposure time segment T2=T1/4 obtained by dividing the first period T1 by 4.

Abstract: In order to determine the locations of individual fluorescent molecules in a sample, which keep a minimum distance with regard to each other, the individual molecules are excited for emission of fluorescence light by means of excitation light. The fluorescence light is registered for different positions of a zero point of an intensity distribution of the excitation light. The distance between these positions is at least half the minimum distance of the fluorescent molecules. The locations of the fluorescent molecules are derived from the course of the intensity of the fluorescence light over the positions of the zero point of the excitation light.