公开(公告)号：US10018552B2

公开(公告)日：2018-07-10

申请号：US15210158

申请日：2016-07-14

Applicant: NIKON CORPORATION

Inventor： Daishi Tanaka ,  Hisao Osawa ,  Kuno Suzuki

IPC: G01N15/00 ,  G01N15/14 ,  G01N21/53 ,  G01N15/10

CPC classification number: G01N15/1459 ,  G01N15/00 ,  G01N15/1463 ,  G01N15/1468 ,  G01N21/53 ,  G01N27/44721 ,  G01N2015/0003 ,  G01N2015/0038 ,  G01N2015/0065 ,  G01N2015/1075 ,  G01N2021/473 ,  G01N2021/4797 ,  G01N2201/12

Abstract: A particle analysis apparatus includes: an acquisition unit that acquires a plurality of images each captured at a different time in each of which a particle moving in a predetermined direction in a medium is imaged; and a determination unit that determines, based on a movement amount of a particle due to Brownian motion in the medium, whether or not an image of a first particle included in an image captured at a first time of the plurality of images acquired by the acquisition unit and an image of a second particle included in an image captured at a second time which is different from the first time of the plurality of images acquired by the acquisition unit are images indicating the same particle.

公开(公告)号：US10012588B2

公开(公告)日：2018-07-03

申请号：US15303726

申请日：2015-04-27

Applicant: COLORIGHT LTD.

Inventor： Efraim Miklatzky ,  Elena Ishkov ,  Daniel Mandelik ,  Gilad Davara

IPC: G01J1/10 ,  G01N21/47 ,  G01J3/46 ,  G01N21/25 ,  G01N21/55 ,  A45D44/00 ,  G01N33/483

CPC classification number: G01N21/47 ,  A45D44/005 ,  A45D2044/007 ,  G01J3/0264 ,  G01J3/463 ,  G01J3/504 ,  G01N21/25 ,  G01N21/4738 ,  G01N21/55 ,  G01N33/4833 ,  G01N2021/4711 ,  G01N2021/4735 ,  G01N2201/12

Abstract: An apparatus and method for customized hair-coloring is disclosed. In some embodiments the method comprises: a. performing a plurality of light-scattering measurements upon a sample of hair such that for each light-scattering measurement, the sample of hair is illuminated from a different respective direction; b. comparing the results of the light-scattering measurements; c. in accordance with results of the comparing, computing an initial damage-state of hair of the sample by comparing the results of the light-scattering measurements; d. obtaining an initial color-state of the hair of the sample; and e. computing a hair-coloring composition that is predicted to transform the hair sample from the initial color-state to a target color-state such that in response to a determining of a greater (lesser) extent of initial damage, a concentration of artificial-colorant(s) within the computed coloring composition is reduced (increased).

公开(公告)号：US20180153410A1

公开(公告)日：2018-06-07

申请号：US15888052

申请日：2018-02-04

Applicant: OMNI MEDSCI, INC.

Inventor： Mohammed N. ISLAM

IPC: A61B5/00 ,  G01J3/42 ,  A61B5/145 ,  A61B5/1455 ,  G01N21/359 ,  G01N21/39 ,  G01N33/49 ,  G01N21/88 ,  G01J3/02 ,  G01J3/10 ,  G01J3/14 ,  G01J3/28 ,  G01N21/3563 ,  G01N21/35 ,  G01N33/44 ,  G01N33/15 ,  G01N33/02 ,  G01J3/453 ,  G01J3/18 ,  G01J3/12 ,  G01M3/38 ,  G01N21/85 ,  G01N21/95 ,  H01S3/00 ,  H01S3/30 ,  H01S3/067

CPC classification number: A61B5/0088 ,  A61B5/0013 ,  A61B5/0022 ,  A61B5/0075 ,  A61B5/0086 ,  A61B5/14532 ,  A61B5/14546 ,  A61B5/1455 ,  A61B5/4547 ,  A61B5/6801 ,  A61B5/7257 ,  A61B5/7405 ,  A61B5/742 ,  A61B2562/0233 ,  A61B2562/0238 ,  A61B2562/146 ,  A61B2576/02 ,  G01J3/0218 ,  G01J3/108 ,  G01J3/14 ,  G01J3/1838 ,  G01J3/28 ,  G01J3/2823 ,  G01J3/42 ,  G01J3/453 ,  G01J2003/104 ,  G01J2003/1208 ,  G01J2003/2826 ,  G01M3/38 ,  G01N21/35 ,  G01N21/3563 ,  G01N21/359 ,  G01N21/39 ,  G01N21/85 ,  G01N21/88 ,  G01N21/9508 ,  G01N33/02 ,  G01N33/025 ,  G01N33/15 ,  G01N33/442 ,  G01N33/49 ,  G01N2021/3595 ,  G01N2021/399 ,  G01N2201/061 ,  G01N2201/06113 ,  G01N2201/062 ,  G01N2201/08 ,  G01N2201/12 ,  G01N2201/129 ,  H01S3/0092 ,  H01S3/06758 ,  H01S3/302

Abstract: An imaging device includes laser diodes (LDs) generating near-infrared wavelength light, lenses configured to deliver the light to tissue, a first receiver having one or more detectors, and a first part with at least one of the LDs capable of being pulsed. The first receiver receives light reflected from the tissue and is synchronized to the pulsed light and configured to perform a time-of-flight measurement. An infrared camera receives light reflected by the tissue from a second part of the imaging device. The camera captures light while the second part is off, and while the second part is on to generate corresponding signals, and differences the signals to generate an image. An array of LDs generates a grid of spots on the tissue, which is reflected to the camera. A coupled phone, tablet, or computer receives and processes the time-of-flight measurement, the image, and the reflected grid of spots.

公开(公告)号：US09989463B2

公开(公告)日：2018-06-05

申请号：US14635848

申请日：2015-03-02

Applicant: CANON KABUSHIKI KAISHA

Inventor： Sandra Skaff ,  Chao Liu

IPC: G01N21/55 ,  G01N21/25 ,  B07C5/342 ,  G01N21/84

CPC classification number: G01N21/55 ,  B07C5/342 ,  G01N21/255 ,  G01N2021/845 ,  G01N2201/0627 ,  G01N2201/12

Abstract: Material classification of an object is provided. Parameters for classification are accessed. The parameters include a selection to select a subset of angles for classification, a selection to select a subset of spectral bands for classification, a selection to capture texture features, and a selection to compute image-level features. The object is illuminated and a feature vector is computed based on the parameters. The material from which the object is fabricated is classified using the feature vector.

公开(公告)号：US09989456B2

公开(公告)日：2018-06-05

申请号：US13781017

申请日：2013-02-28

Applicant: Facet Technology Corp.

Inventor： Jamie E. Retterath ,  Robert A. Laumeyer

IPC: G06K9/00 ,  G01N21/25 ,  G08G1/0967 ,  G01N21/55 ,  G01N21/84 ,  G01S17/06 ,  G06K9/20 ,  G06K9/46

CPC classification number: G01N21/251 ,  G01N21/55 ,  G01N21/84 ,  G01N2201/06113 ,  G01N2201/102 ,  G01N2201/12 ,  G01S17/06 ,  G06K9/00791 ,  G06K9/00818 ,  G06K9/2036 ,  G06K9/4652 ,  G06K9/4661 ,  G08G1/096758 ,  G08G1/096783

Abstract: A system for the determination of retroreflectivity values for reflective surfaces disposed along a roadway repeatedly illuminates an area along the roadway that includes at least one reflective surface using a light source. Multiple light intensity values are measured over a field of view which includes at least a portion of the area illuminated by the light source. A computer processing system is used to identifying a portion of the light intensity values associated with a reflective surface and analyze the portion of the light intensity values to determine at least one retroreflectivity value for that reflective surface.

公开(公告)号：US09986165B2

公开(公告)日：2018-05-29

申请号：US14588032

申请日：2014-12-31

Applicant: Invent.ly LLC

Inventor： Stephen J Brown

IPC: G01R35/00 ,  H04N5/232 ,  G06F19/00 ,  G01N21/84 ,  H04N7/18

CPC classification number: H04N5/23293 ,  G01N21/8483 ,  G01N2201/12 ,  G06F19/00 ,  G06F19/3418 ,  G16H10/40 ,  G16H40/67 ,  H04N5/23206 ,  H04N7/18

Abstract: A system includes an apparatus having a test medium with a machine-readable identifier, the medium enabled to accept an analyte for a test, a network-connected communication device having imaging capability, enabled to record contextual information, and executing coded instructions, a server having coupled to at least one data repository, and coded instructions executing on a processor. A user applies the analyte to the test medium, allows time to complete, and initiates an image capture, wherein a data structure, including at least a resulting image, images or video stream, including one or more images of the test result, one or more images of the machine-readable identifier, contextual information captured at the time of the test and identify of the test subject providing the analyte, is transmitted on the network to the network-connected server, where the data structure is recorded.

公开(公告)号：US09970923B2

公开(公告)日：2018-05-15

申请号：US15251370

申请日：2016-08-30

Applicant: Church & Dwight Co., Inc.

Inventor： Andy Sturman ,  Benedict Zin ,  Albert Nazareth ,  Henry Bell

IPC: G01N21/03 ,  G01N33/487 ,  G01N21/84 ,  G01N21/17 ,  G01N33/493 ,  G01N33/62 ,  G01N33/68 ,  G01N33/76

CPC classification number: G01N33/48792 ,  G01N21/17 ,  G01N21/8483 ,  G01N33/48785 ,  G01N33/493 ,  G01N33/62 ,  G01N33/689 ,  G01N33/76 ,  G01N2201/062 ,  G01N2201/12 ,  G01N2333/59

Abstract: An improved electronic diagnostic device for detecting the presence of an analyte in a fluid sample comprises a casing having a display, a test strip mounted in the casing, a processor mounted in the casing, and a first sensor mounted in the casing and operatively coupled to the processor. The processor is configured to receive a signal from the first sensor when the device is exposed to ambient light thereby causing the device to become activated. The device includes a light shield that exerts pressure across a width of the test strip to prevent fluid channeling along the length of the test strip. The processor is configured to present an early positive test result reading when a measured value exceeds a predetermined early reading threshold value at any time after a predetermined early testing time period.

公开(公告)号：US09958328B2

公开(公告)日：2018-05-01

申请号：US15551599

申请日：2016-02-23

Applicant: CI SYSTEMS (ISRAEL) LTD.

Inventor： Dario Cabib ,  Amir Gil ,  Moshe Lavi ,  Liviu Singher

IPC: G01J3/28 ,  G01J3/02 ,  G01N21/3504

CPC classification number: G01J3/2823 ,  G01J3/0205 ,  G01J3/2803 ,  G01J3/36 ,  G01N21/3504 ,  G01N2201/12

Abstract: Devices image radiation from a scene that includes two materials with spectral characteristics in two different wavelength regions. A lens forms an image of the scene on a detector that includes an array of elements. A filtering arrangement integrated with the detector allows half of the detector elements to detect radiation in one of the wavelength regions and the other half of the detector elements to detect radiation in the other wavelength region. Each detector element can be constructed from two different sub-elements that are sensitive to radiation in one of the respective wavelength regions. A blackbody source positioned within the devices reduces drift induced by changes to the environment surrounding the devices. The blackbody source projects radiation onto a region of the detector that does not receive radiation from the scene. Pixel signals produced from the scene radiation are modified based on pixel signals produced from the blackbody.

公开(公告)号：US20180080879A1

公开(公告)日：2018-03-22

申请号：US15701746

申请日：2017-09-12

Applicant: DELTA ELECTRONICS, INC.

Inventor： Ming-Shu LIN ,  Ying-Ting CHEN ,  Wang-Chu CHEN ,  Ching-Yu CHANG

IPC: G01N21/78

CPC classification number: G01N21/78 ,  G01N2021/7759 ,  G01N2021/7783 ,  G01N2201/062 ,  G01N2201/12

Abstract: An optical detection system includes a light emitting module, a test strip and a receiving module. The light emitting module includes a light source and a first light shielding unit. The first light shielding unit has a first aperture corresponding to the light source. The test strip includes a cassette and a light permeable test paper. The cassette has a first window, a second window and a sample opening disposed on one surface of the cassette. The first and second windows are disposed corresponding to each other and located on opposite sides of the cassette, respectively. The light permeable test paper is disposed in the cassette. The receiving module includes a second light shielding unit and a photo sensor. The second light shielding unit has a second aperture corresponding to the second window. The photo sensor receives the light beam from the light source and outputs a measurement signal.

公开(公告)号：US09921156B2

公开(公告)日：2018-03-20

申请号：US14765690

申请日：2014-01-31

Applicant: Anand T. N. Kumar

Inventor： Anand T. N. Kumar

IPC: G01N21/64 ,  G01N33/483

CPC classification number: G01N21/6408 ,  G01N33/4833 ,  G01N2021/6439 ,  G01N2201/06113 ,  G01N2201/12

Abstract: A system and method for determining fluorescence decay in a biological sample is provided. The method includes acquiring optical signal data from at least a part of a biological sample undergoing fluorescence, assembling the optical signal data into a set of spatial time-series data, and converting the set of spatial time-series data into a set of spatial frequency time-series data. The method also includes applying a spatial filter to the set of spatial frequency time-series data to yield a set of filtered frequency-series data, the spatial filter configured to separate, from the set of frequency-series data, fluorescence signals consistent with a non-diffuse component and converting the set of filtered frequency-series data into a set of filtered time-series data. The method further includes determining, using the filtered time-series data, a fluorescence signature consistent with fluorescence decay of at least one fluorophore, and generating a report indicative of the fluorescence signature of the biological sample.