Abstract: A system for detecting the presence of an analyte in a moving substrate or sample handling device is disclosed, providing means (26,30) for integrated triggering of data acquisition with a detector means (28) and data acquisition with a detector means (28). In particular, a surface Plasmon resonance “lab on disk” reader system is disclosed.
Type:
Grant
Filed:
December 7, 2010
Date of Patent:
April 21, 2015
Assignee:
Biosurfit, S.A.
Inventors:
João Garcia Da Fonseca, João Dias Pedro Nicolau Manso, Pedro Miguel Monteiro Gomes, Sandro Miguel Pinto Bordeira, José Pedro Santos Manso Côrte-Real
Abstract: A gas analyzer is capable of detecting abnormality of a measurement environment without using either or both of a pressure sensor and a gas temperature sensor. The gas analyzer creates absorption spectra from transmitted light intensity of laser beams applied to gas for measuring the amount of spread W and compares the amount of spread against a threshold D. The amount of spread of the absorption spectra does not depend on pressure if the pressure of the gas to be measured falls within a high-vacuum region, and monotonously increases with increased pressure if the pressure of the gas to be measured is higher than the high-vacuum region. Thus, if W>D, it is determined that the measurement environment does not form a high-vacuum region and abnormality is transmitted to the outside. In all other cases, the measurement environment is deemed to form a high-vacuum region, and partial pressure is calculated.
Abstract: A method includes determining particle size distribution (PSD) in a fluid flow line based on a range of sizes for at least one particle in the fluid flow line and duration of reflection of a laser beam from the at least one particle. The laser beam is focused from a laser beam instrument in direct contact with the fluid low line.
Abstract: The present invention provides a fiber laser gas detection system using active feedback compensation by a reference cavity, said system comprising: an optical fiber laser consists of a laser diode pump source, a wavelength division multiplexer, an active optical fiber and a fiber Bragg grating connected successively; an optical isolator coupled with said wavelength division multiplexer for blocking a reverse light transmission in said active fiber; a coupler connected with said optical isolator for dividing the laser light after being isolated by the optical isolator into a reference beam, a detecting beam and an intensity measuring beam according a certain ration power. The gas detection system according to the present invention can take advantages of the unique superiority of compact structure and narrow linewidth of the laser output of the fiber laser, and achieve a gas detection method with high sensitive and high precision by feedback controlling.
Type:
Grant
Filed:
October 1, 2014
Date of Patent:
April 14, 2015
Assignee:
Beijing Information Science & Technology University
Abstract: A method for detecting a coating on a bottle includes directing light at a first point of incidence on the bottle and detecting a first intensity of reflected light from the first point of incidence on the bottle. Further, light is directed at a second point of incidence on the bottle and a second intensity of reflected light from the second point of incidence on the bottle is detected. The first intensity is compared to the second intensity to determine whether the coating on the bottle has been uniformly deposited.
Type:
Grant
Filed:
May 14, 2012
Date of Patent:
February 3, 2015
Assignee:
Nano Scale Surface Systems, Inc.
Inventors:
John Thomas Felts, Christopher John Felts
Abstract: A semiconductor inspection apparatus (100) is an apparatus for inspecting a semiconductor device. The semiconductor inspection apparatus (100) includes a pulsed laser light source (14) for emitting pulsed laser light (2) toward a substrate (1) with a semiconductor device formed thereon, an electromagnetic wave pulse application part (18) for applying a reverses-biasing electromagnetic wave pulse (4) for applying a reverse bias to an application position (10) which receives the pulsed laser light (2), and a detection part (17) for detecting an electromagnetic wave pulse (3) emitted from the application position (10) in response to the application of the pulsed laser light (2).
Type:
Grant
Filed:
September 15, 2012
Date of Patent:
January 27, 2015
Assignees:
Dainippon Screen Mfg. Co., Ltd., Osaka University
Abstract: Methods and Apparatuses are provided for a thin high contrast optical acquisition system for fingerprint recognition. In one embodiment, an apparatus for determining validity of a fingerprint includes a light refracting device (light refractor), a light source, a light collecting device, and a controller. The light refracting device can, for example, be a TFT light panel structure or an active matrix organic light emitting diode (AMOLED) panel structure with reverse current measurement and amplification circuitry, and includes an imaging surface and a viewing plane. Incident light from the light source is projected directly or indirectly onto the imaging surface to create an image of the patterned object from the projected light onto the viewing plane. The apparatus is configured to have a thin form factor, which may be flexible or conformable, compared to conventional optical fingerprint acquisition apparatuses.
Abstract: A device for measuring three dimensional shape is configured to perform one of a first imaging operation as imaging processing of a single operation among a multiplicity of imaging operations performed by irradiation of a first light pattern of multiply varied phases, and a second imaging operation as imaging processing of a single operation among a multiplicity of imaging operations performed by irradiation of a second light pattern of multiply varied phases. The device is configured to, simultaneous with completion of the first or second imaging operation, start shifting or switching operation of said first grating or a second grating relating to said first imaging operation. The device is configured to, without waiting for completion of the shifting or switching operation, perform the other imaging operation from among the first and second imaging operations.
Abstract: A method includes measuring intensities of light passing through a sample of an algae culture at different wavelengths. The method also includes identifying, using the measured intensities, a peak absorption wavelength of at least one type of chlorophyll in the sample and/or an absorption ratio involving multiple types of chlorophyll in the sample. The method further includes determining whether the algae culture has a problem using the peak absorption wavelength and/or the absorption ratio. The peak absorption wavelength could be identified by identifying a specified wavelength at which a smallest amount of light passes through the sample. The absorption ratio could be identified by identifying an average absorption wavelength of first and second types of chlorophyll in the sample and identifying a peak absorption wavelength of the first type of chlorophyll.
Abstract: An optical device includes a group of projections projecting from a conductor surface of a substrate, and arranged along a first direction at a pitch Px, a dielectric layer covering the conductor surface and the group of projections, and a metal nanostructure having metal nanoparticles each having a size d of the order of nanometers arranged on the dielectric layer along the first direction, assuming that the wavelength of irradiation light is ?, ?>Px>d is fulfilled, and assuming that a maximum value of an arrangement pitch between two of the metal nanoparticles adjacent to each other in the first direction is Qx, Px>Qx is fulfilled.
Type:
Grant
Filed:
June 22, 2012
Date of Patent:
September 16, 2014
Assignee:
Seiko Epson Corporation
Inventors:
Jun Amako, Kohei Yamada, Tatsunori Miyazawa
Abstract: A device for detecting the level of a liquid in a container, includes an optical structure facing at least partly the region inside the container in a position corresponding to a predefined level of the liquid and having a main surface, a first side surface and a second side surface which are inclined at about 45° with respect to the main surface and about 90° relative to each other; and an emitter and a receiver facing the main surface of the optical structure and able to send a radiation beam towards the first side surface and, respectively, receive a radiation beam emitted by the emitter and reflected by the first and second side surfaces, when the level of the liquid inside the container is lower than the predefined level. The structure extends mainly outside the container and faces the region inside the container only opposite the first side surface.
Abstract: An apparatus for detecting defects of elements to be subjected to examination, particularly metallic lids, with means for lighting an element to be subjected to examination, an image acquisition unit, and a unit for processing images acquired by said image acquisition unit is described.
Abstract: An automated analysis method for an impactor used as a measuring transducer for the selective determination of oil mist or aerosols. The process includes the steps of rotating the deflector plate (5) of the measuring transducer (1) about the symmetry axis thereof and of determining the quantity of oil deposited by means of an optical analyzing device from the extinction of a light beam reflected from deflector plate (5) due to the alternation between the background and the pattern produced by the micronozzles (4).
Type:
Grant
Filed:
May 17, 2012
Date of Patent:
July 1, 2014
Assignee:
Dräger Safety AG & Co. KGaA
Inventors:
Andreas Seeck, Ralf Strothmann, Andreas Mohrmann
Abstract: A standard media suspension body (150) for verification and calibration of an optical particulate measurement instrument and configured to be at least partially immersed in a sample fluid is provided according to the invention. The body (150) includes a substantially solid outer surface including a first end (151) and a second end (152) disposed along an axis of illumination A and at least one outer surface (153). The first end (151) is configured to admit impinging light. The suspension body further includes an inner volume. At least a portion of the inner volume includes a substantially suspended light scattering material (155) that is configured to scatter a predetermined quantum of the admitted light. The suspension body (150) further includes an end cap (156) formed on the second end (152) and comprising a light absorbing material. Light exiting the second end (152) is substantially absorbed by the end cap (156).
Abstract: The present disclosure relates to the field characterization of particles in a sample solution. More specifically, the present disclosure relates to a flow cell and a method for characterizing particles by means of collected non-Gaussian temporal signals. The present flow cell and method rely on an excitation fiber with a channel. The excitation fiber has a core for transporting an excitation light generated by a light source, and defines a channel through a portion of its core. The channel of the excitation fiber directs a flow of the sample solution. The excitation fiber, the channel and collection fibers characteristics are selected, proportioned and positioned to generate collected light with a non-Gaussian temporal intensity profile.
Type:
Grant
Filed:
August 16, 2013
Date of Patent:
May 27, 2014
Assignee:
Handyem Inc.
Inventors:
Dany Nolet, Alain Chandonnet, Michel Fortin
Abstract: A method of completing a hydrocarbon lateral well in a target shale formation. The method uses a data log generated from an optical flow cell assembly to identify areas in the lateral well of high free gas porosity. By evaluating such data, an operator can group “like” rock, determine stage length and variation in stage length, and determine perforation cluster spacing and location. The flow cell assembly can also be used in a completion program to assist in the steering of a lateral well being drilled below the target formation.
Abstract: A fine particle detector includes a light emitting system letting light from a light source pass through a phase difference element and focusing the light on a sample flow through which fine particles flow. When the direction of the sample flow is an X-axis direction, the light is emitted to the sample flow in a Z-direction, and a ZX-plane is orthogonal to a Y-direction, then the phase difference element has a plurality of regions divided in the Y-axis direction and causes a phase difference between wavefronts of the light passing through the plurality of regions.
Abstract: A sensor having a housing with a first member connected to a second member to form a circular central opening. A plurality of photoelectric transmitters and receivers are placed between the first member and the second member such that each receiver is within a liner-of-sight of each transmitter across the central opening and the signals sent between the receivers and transmitters fills an area of detection.