公开(公告)号：US3537795A

公开(公告)日：1970-11-03

申请号：US3537795D

申请日：1967-11-29

Applicant: COMMISSARIAT ENERGIE ATOMIQUE

Inventor： CLERC MICHEL

IPC: G01J3/06 ,  G01N21/34

CPC classification number: G01J3/06

公开(公告)号：US3437412A

公开(公告)日：1969-04-08

申请号：US3437412D

申请日：1965-06-17

Applicant: PIERRE RAOUL JOSEPH STEHLE

Inventor： STEHLE PIERRE RAOUL JOSEPH

IPC: G01J3/06 ,  G01J3/00 ,  G02B5/18

CPC classification number: G01J3/06 ,  Y10T74/1836

公开(公告)号：US3229563A

公开(公告)日：1966-01-18

申请号：US9184561

申请日：1961-02-27

Applicant: PERKIN ELMER CORP

Inventor： MEY II CHARLES F DE

IPC: G01J3/06

CPC classification number: G01J3/06

公开(公告)号：US20240319010A1

公开(公告)日：2024-09-26

申请号：US18186906

申请日：2023-03-20

Applicant: THERMO ELECTRON SCIENTIFIC INSTRUMENTS LLC

Inventor： John Iverson ,  Garry Ritter ,  Pete Knudtson ,  Eric Schwartz

IPC: G01J3/453 ,  G01J3/06

CPC classification number: G01J3/4535 ,  G01J3/06 ,  G01J2003/064 ,  G01J2003/4538

Abstract: Interfering internal beams can be used to generate an internal reference interferogram. This interferogram can be used to compensate for changes in FTIR instrument performance in response to variable environmental conditions or other instrument variations. Acquisition of such internal interferograms can be done during, after, or prior to acquisition of actual sample data.

公开(公告)号：US20240302211A1

公开(公告)日：2024-09-12

申请号：US18599387

申请日：2024-03-08

Applicant: SEIKO EPSON CORPORATION

Inventor： Masaki ITO ,  Takeshi TOKUDA

IPC: G01J3/06 ,  G01J3/02

CPC classification number: G01J3/06 ,  G01J3/0202 ,  G01J2003/061 ,  G01J2003/062

Abstract: A color measurement apparatus to which a colorimeter that measures a color of a color measurement target is configured to be attached, includes a support base of the color measurement target, a carriage that supports the colorimeter, a gantry that supports the carriage, a first scanning mechanism that causes the carriage to perform scanning in a first direction on the support base, and a second scanning mechanism that causes the gantry to perform scanning in a second direction, in which the first scanning mechanism includes a first motor that generates a driving force for causing the carriage to perform scanning in the first direction, and a first transmission mechanism portion that transmits the driving force from the first motor to the carriage, and the first motor overlaps the gantry in a third direction.

公开(公告)号：US20240159588A1

公开(公告)日：2024-05-16

申请号：US18410593

申请日：2024-01-11

Applicant: Pendar Technologies, LLC

Inventor： Daryoosh VAKHSHOORI ,  Romain BLANCHARD ,  Peili CHEN ,  Masud AZIMI ,  Tobias MANSURIPUR ,  Kalyani KRISHNAMURTHY ,  Arran M. BIBBY ,  Fred R. HUETTIG, III ,  Gokhan ULU ,  Greg Vander Rhodes

IPC: G01J3/02 ,  G01J3/06 ,  G01J3/28 ,  G01J3/44 ,  G01K11/3213 ,  H01S3/00 ,  H01S3/094 ,  H01S3/108 ,  H01S3/30

CPC classification number: G01J3/0275 ,  G01J3/0202 ,  G01J3/0208 ,  G01J3/0216 ,  G01J3/0224 ,  G01J3/0237 ,  G01J3/0248 ,  G01J3/0256 ,  G01J3/0264 ,  G01J3/0272 ,  G01J3/0286 ,  G01J3/06 ,  G01J3/2823 ,  G01J3/44 ,  G01J3/4406 ,  G01J3/4412 ,  G01K11/3213 ,  H01S3/0014 ,  H01S3/094046 ,  H01S3/1086 ,  H01S3/302 ,  G01J2003/4424 ,  G01K11/324 ,  H01S3/0071

Abstract: A compact, portable Raman spectrometer makes fast, sensitive standoff measurements at little to no risk of eye injury or igniting the materials being probed. This spectrometer uses differential Raman spectroscopy and ambient light measurements to measure point-and-shoot Raman signatures of dark or highly fluorescent materials at distances of 1 cm to 10 m or more. It scans the Raman pump beam(s) across the sample to reduce the risk of unduly heating or igniting the sample. Beam scanning also transforms the spectrometer into an instrument with a lower effective safety classification, reducing the risk of eye injury. The spectrometer's long standoff range automatic focusing make it easier to identify chemicals through clear and translucent obstacles, such as flow tubes, windows, and containers. And the spectrometer's components are light and small enough to be packaged in a handheld housing or housing suitable for a small robot to carry.

公开(公告)号：US20240044709A1

公开(公告)日：2024-02-08

申请号：US18214974

申请日：2023-06-27

Applicant: Nanchang Hangkong University

Inventor： Jiulin SHI ,  Jin XU ,  Tianchi SUN ,  Liangya CUI ,  Xin LAN ,  Mingxuan LIU ,  Xingdao HE

IPC: G01J3/44 ,  G01J3/02 ,  G01J3/453 ,  G01J3/06

CPC classification number: G01J3/4412 ,  G01J3/0224 ,  G01J3/0294 ,  G01J3/0229 ,  G01J3/0208 ,  G01J3/4537 ,  G01J3/06 ,  G01J3/0278 ,  G01J3/027

Abstract: Disclosed is a linear array scanning Brillouin scattering elastic imaging device. In the device, a signal generating system consists of a narrow linewidth continuous wave laser, a half-wave plate, a beam expander, a Y-direction scanning galvanometer, a microlens array, a pinhole array filter, a first plano-convex lens, a polarization beam splitter, a quarter-wave plate and a microscope objective. A signal receiving system consists of a microscope objective, a quarter-wave plate, a polarization beam splitter and an eight-channel optical collimator array. Each channel of an eight-channel spectrometer consists of an optical collimator, a convex lens, a scanning Fabry-Perot interferometer, a photomultiplier tube and an eight-channel photon collection card.

公开(公告)号：US11885681B2

公开(公告)日：2024-01-30

申请号：US17705846

申请日：2022-03-28

Applicant: Pendar Technologies, LLC

Inventor： Daryoosh Vakhshoori ,  Romain Blanchard ,  Peili Chen ,  Masud Azimi ,  Tobias Mansuripur ,  Kalyani Krishnamurthy ,  Arran M. Bibby ,  Fred R. Huettig, III ,  Gokhan Ulu ,  Greg Vander Rhodes

IPC: G01J3/02 ,  G01J3/44 ,  G01J3/28 ,  G01J3/06 ,  H01S3/00 ,  G01K11/3213 ,  H01S3/094 ,  H01S3/108 ,  H01S3/30 ,  G01K11/324

CPC classification number: G01J3/0275 ,  G01J3/0202 ,  G01J3/0208 ,  G01J3/0216 ,  G01J3/0224 ,  G01J3/0237 ,  G01J3/0248 ,  G01J3/0256 ,  G01J3/0264 ,  G01J3/0272 ,  G01J3/0286 ,  G01J3/06 ,  G01J3/2823 ,  G01J3/44 ,  G01J3/4406 ,  G01J3/4412 ,  G01K11/3213 ,  H01S3/0014 ,  H01S3/094046 ,  H01S3/1086 ,  H01S3/302 ,  G01J2003/4424 ,  G01K11/324 ,  H01S3/0071

Abstract: A compact, portable Raman spectrometer makes fast, sensitive standoff measurements at little to no risk of eye injury or igniting the materials being probed. This spectrometer uses differential Raman spectroscopy and ambient light measurements to measure point-and-shoot Raman signatures of dark or highly fluorescent materials at distances of 1 cm to 10 m or more. It scans the Raman pump beam(s) across the sample to reduce the risk of unduly heating or igniting the sample. Beam scanning also transforms the spectrometer into an instrument with a lower effective safety classification, reducing the risk of eye injury. The spectrometer's long standoff range automatic focusing make it easier to identify chemicals through clear and translucent obstacles, such as flow tubes, windows, and containers. And the spectrometer's components are light and small enough to be packaged in a handheld housing or housing suitable for a small robot to carry.

公开(公告)号：US20190145891A1

公开(公告)日：2019-05-16

申请号：US16129731

申请日：2018-09-12

Applicant: MultiSensor Scientific, Inc.

Inventor： Allen M. Waxman ,  Terrence K. Jones ,  Jason M. Bylsma ,  Stefan Bokaemper

IPC: G01N21/3504 ,  G01N33/22

CPC classification number: G01N21/3504 ,  E21B41/0021 ,  G01F1/661 ,  G01J3/0208 ,  G01J3/021 ,  G01J3/06 ,  G01J3/10 ,  G01J3/2803 ,  G01J3/2823 ,  G01J3/42 ,  G01J2003/1213 ,  G01J2003/1221 ,  G01J2003/2806 ,  G01J2003/2826 ,  G01M3/20 ,  G01M3/38 ,  G01N21/359 ,  G01N33/0036 ,  G01N33/225 ,  G01N2021/1795 ,  G01N2021/3513 ,  G01N2201/101

Abstract: Presented herein are systems and methods directed to a multispectral absorption-based imaging approach that provides for rapid and accurate detection, localization, and quantification of gas leaks. The imaging technology described herein utilizes a scanning optical sensor in combination with structured and scannable illumination to detect and image spectral signatures produced by absorption of light by leaking gas in a quantitative manner over wide areas, at distance, and in the presence of background such as ambient gas and vapor. Moreover, the specifically structured and scannable illumination source of the systems and methods described herein provides a consistent source of illumination for the scanning optical sensor, allowing imaging to be performed even in the absence of sufficient natural light, such as sunlight. The imaging approaches described herein can, accordingly, be used for a variety of gas leak detection, emissions monitoring, and safety applications.

公开(公告)号：US20180274978A1

公开(公告)日：2018-09-27

申请号：US15768714

申请日：2017-08-10

Applicant: Shenzhen Institute of Terahertz Technology and Innovation ,  Shenzhen Terahertz System Equipment Co., Ltd.

Inventor： Qing Ding ,  Shichang Peng ,  Yi Pan ,  Chen Li

IPC: G01J3/02 ,  G01J3/06 ,  G01J3/42 ,  G01N21/3586

CPC classification number: G01J3/0208 ,  G01J3/06 ,  G01J3/42 ,  G01J2003/064 ,  G01J2003/423 ,  G01N21/3586 ,  G02B26/06

Abstract: A delay line device and a terahertz time-domain spectrometer system include: a baseplate, a slide rail component, in which the slide rail component includes a slide, a reflector, a grating ruler component, and an electric-magnetic induction component. When the electric-magnetic component, after being applied a current, cuts the magnetic induction coil to generate power to push the slide moving, the grating ruler component placed on the slide rail component collects the movement information of the slide. The slide's movement drives the reflector placed on the slide to move together to change the optical distance of a pump light, so as to generate the delay between the pump light and a probe light.The changes to the abstract are shown below:A delay line device and a terahertz time-domain spectrometer system include: a baseplate, a slide rail component, in which the slide rail component includes a slide, a reflector, a grating ruler component, and an electric-magnetic induction component. When the electric-magnetic component, after being applied a current, cuts the magnetic induction coil to generate power to push the slide moving, the grating ruler component placed on the slide rail component collects the movement information of the slide. The slide's movement drives the reflector placed on the slide to move together to change the optical distance of a pump light, so as to generate the delay between the pump light and a probe light.