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公开(公告)号:US09453764B2
公开(公告)日:2016-09-27
申请号:US14805221
申请日:2015-07-21
Applicant: H2Optx Inc.
Inventor: Rudolf J. Hofmeister , Donald A. Ice , Scott W. Tandy
IPC: G01N21/25 , G01J3/42 , G01J3/44 , G01J3/06 , G01J3/10 , B01D46/00 , B01D46/42 , G01N1/06 , G01N33/15 , G01N21/01 , G01N23/00 , G01N35/10 , G01N21/3504 , G01J3/00 , G01N21/33 , G01N21/3577 , G01N21/65
CPC classification number: G01J3/42 , B01D46/0002 , B01D46/42 , G01J3/00 , G01J3/0267 , G01J3/0291 , G01J3/06 , G01J3/10 , G01J3/44 , G01N1/06 , G01N21/01 , G01N21/25 , G01N21/253 , G01N21/33 , G01N21/3504 , G01N21/3577 , G01N21/65 , G01N23/00 , G01N33/15 , G01N35/10 , G01N2021/0106 , G01N2201/0231
Abstract: The present disclosure generally relates to systems, devices and methods for analyzing and processing samples or analytes. In one example configuration, a method of analyzing an analyte includes shaving a first layer of a plurality of layers of an analyte to expose a first surface of an analyte. The method includes positioning the first surface of the analyte over a window of a hyperspectral analyzation subassembly. The method further includes scanning the first surface of the analyte by the hyperspectral analyzation subassembly to obtain information regarding the analyte proximate the first surface. Other systems, devices and methods are disclosed herein.
Abstract translation: 本公开一般涉及用于分析和处理样品或分析物的系统,装置和方法。 在一个示例性配置中,分析分析物的方法包括剃刮分析物的多个层的第一层以暴露分析物的第一表面。 该方法包括将分析物的第一表面定位在高光谱分析子组件的窗口上。 该方法还包括通过高光谱分析子组件扫描分析物的第一表面以获得关于第一表面附近的分析物的信息。 本文公开了其它系统,装置和方法。
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公开(公告)号:US20160238535A1
公开(公告)日:2016-08-18
申请号:US15140707
申请日:2016-04-28
Applicant: SciAps, Inc.
Inventor: David R. Day , Konstantin Derman , John Francis Egan , Paul Edward Soucy
CPC classification number: G01J3/0272 , G01J3/0208 , G01J3/0291 , G01J3/10 , G01J3/2823 , G01J3/443 , G01J2003/2879 , G01N21/718 , G01N2201/0221 , G01N2201/06113 , G01N2201/0633
Abstract: A handheld LIBS spectrometer includes an optics stage movably mounted to a housing and including a laser focusing lens and a detection lens. One or more motors advance and retract the optics stage, move the optics stage left and right, and/or move the optics stage up and down. A laser source in the housing is oriented to direct a laser beam to the laser focusing lens. A spectrometer subsystem in the housing is configured to receive electromagnetic radiation from the detection lens and to provide an output. A controller subsystem is responsive to the output of the spectrometer subsystem and is configured to control the laser source and motors. In this way, auto-calibration, auto-clean, and auto-focus, and/or moving spot functionality is possible.
Abstract translation: 手持式LIBS光谱仪包括可移动地安装到壳体并包括激光聚焦透镜和检测透镜的光学台。 一个或多个电机推进和缩回光学平台,左右移动光学台,和/或上下移动光学平台。 壳体中的激光源被定向成将激光束引导到激光聚焦透镜。 外壳中的光谱仪子系统被配置为从检测透镜接收电磁辐射并提供输出。 控制器子系统响应于光谱仪子系统的输出,并被配置为控制激光源和电动机。 这样就可以进行自动校准,自动清理和自动对焦,和/或移动点功能。
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公开(公告)号:US20160231171A1
公开(公告)日:2016-08-11
申请号:US14614575
申请日:2015-02-05
Applicant: International Business Machines Corporation
CPC classification number: G01J3/2823 , G01J3/0264 , G01J3/0272 , G01J3/0291 , G01J3/10 , G01J3/18
Abstract: The present invention discloses a spectrometer apparatus comprising a mobile device including an integrated camera, having a camera lens and an image sensor. The camera lens is located within a body of the mobile device that comprises a detachable housing coupled to the body of the mobile device. The detachable housing includes a first end and a second end opposed to the first end. The first end includes an optical input and the second end includes an opening that is substantially aligned with the camera lens. An optical spectrometer device is located within the housing and optically coupled to both the optical input at the first end of the housing and the camera lens at the second end of the housing. The optical spectrometer device receives a target image from the optical input and generates a spectral image that is received by the image sensor via the camera lens.
Abstract translation: 本发明公开了一种光谱仪装置,包括具有相机镜头和图像传感器的集成照相机的移动装置。 摄像机镜头位于移动设备的主体内,其包括联接到移动设备的主体的可拆卸外壳。 可拆卸外壳包括与第一端相对的第一端和第二端。 第一端包括光学输入端,第二端部包括基本上与相机透镜对准的开口。 光学仪器装置位于壳体内,并且在壳体的第一端处的光学输入端和光学耦合到壳体的第二端处的相机透镜。 光谱仪装置从光学输入接收目标图像,并生成由图像传感器经由照相机镜头接收的光谱图像。
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公开(公告)号:US09372152B2
公开(公告)日:2016-06-21
申请号:US14637094
申请日:2015-03-03
Applicant: MKS Instruments, Inc.
Inventor: Charles Mark Phillips , Barbara Marshik-Geurts , Leonard I. Kamlet , Martin L. Spartz , Vidi Saptari
IPC: G01B9/02 , G01J3/45 , G01N21/3504 , G01J3/02 , G01J3/42 , G01N21/03 , G01N21/45 , G01J3/453 , G01N21/05 , G01N21/09 , G01N21/35
CPC classification number: G01N21/3504 , G01J3/02 , G01J3/0291 , G01J3/42 , G01J3/453 , G01N21/031 , G01N21/05 , G01N21/09 , G01N21/45 , G01N2021/3595 , G01N2201/061 , G01N2201/0636 , G01N2201/1293
Abstract: A method is provided for monitoring one or more silicon-containing compounds present in a biogas. The method includes generating a first absorption spectrum based on a ratio of a first spectral measurement and a second spectral measurement. The first spectral measurement is from a non-absorptive gas having substantially no infrared absorptions in a specified wavelength range of interest and the second spectral measurement is from a sample gas comprising the biogas. The method includes generating at least one surrogate absorption spectrum based on, at least, individual absorption spectrum for each of a subset of one or more silicon-containing compounds selected from a larger set of known silicon-containing compounds with known concentrations. A total concentration of the one or more silicon-containing compounds in the biogas can be calculated based on the first absorption spectrum and the at least one surrogate absorption spectrum.
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公开(公告)号:US09360366B1
公开(公告)日:2016-06-07
申请号:US14879037
申请日:2015-10-08
Applicant: Chuong Van Tran
Inventor: Chuong Van Tran
CPC classification number: G01J3/10 , G01J3/0205 , G01J3/0229 , G01J3/0256 , G01J3/0264 , G01J3/0272 , G01J3/0291 , G01J3/04 , G01J3/28 , G01J3/2803 , G01J2003/2866 , H04M1/72527 , H04M2250/52
Abstract: This invention discloses a self-referencing spectrometer that simultaneously auto-calibrate and measure optical spectra of physical object utilizing shared aperture as optical inputs. The concurrent measure and self-calibrate capabilities makes it possible as an attachment spectrometer on a mobile computing device without requiring an off-line calibration with an external reference light source. Through the mobile computing device, the obtained spectral information and imagery captured can be distributed through the wireless communication networks.
Abstract translation: 本发明公开了一种自参照光谱仪,其同时自动校准和测量利用共享孔径作为光输入的物理物体的光谱。 并行测量和自校准功能使得作为移动计算设备上的附件光谱仪成为可能,而不需要使用外部参考光源进行离线校准。 通过移动计算设备,所获得的光谱信息和图像可以通过无线通信网络分布。
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公开(公告)号:US09354365B2
公开(公告)日:2016-05-31
申请号:US14166248
申请日:2014-01-28
Applicant: Lumentum Operations LLC
Inventor: Sheldon McLaughlin
CPC classification number: G02B6/29313 , G01J3/02 , G01J3/0205 , G01J3/0208 , G01J3/021 , G01J3/0243 , G01J3/0256 , G01J3/0291 , G01J3/1804 , G01J3/22 , G02B5/12 , G02B5/1809 , G02B5/1814 , G02B5/1866 , G02B6/2931 , G02B6/29311 , G02B6/2938 , G02B6/354 , G02B17/0856 , G02B2005/1804
Abstract: A compact wavelength dispersing device and a wavelength selective optical switch based on the wavelength dispersing device is described. The wavelength dispersing device has a folding mirror that folds the optical path at least three times. A focal length of a focusing coupler of the device is reduced and the NA is increased, while the increased optical aberrations are mitigated by using an optional coma-compensating wedge. A double-pass arrangement for a transmission diffraction grating allows further focal length and overall size reduction due to increased angular dispersion.
Abstract translation: 描述了基于波长分散装置的紧凑型波长分散装置和波长选择光开关。 波长分散装置具有将光路折叠至少三次的折叠镜。 减少了设备的聚焦耦合器的焦距,并且增加了NA,同时通过使用可选的光阑补偿楔来减轻增加的光学像差。 用于透射衍射光栅的双通道布置允许由于增加的角度分散而使焦距和总体尺寸减小。
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公开(公告)号:US20160146668A1
公开(公告)日:2016-05-26
申请号:US14903530
申请日:2014-06-17
Applicant: SHIMADZU CORPORATION
Inventor: Takahide HATAHORI , Naoji MORIYA
CPC classification number: G01J3/44 , G01J3/0208 , G01J3/021 , G01J3/0218 , G01J3/0224 , G01J3/0262 , G01J3/0291 , G01N21/05 , G01N21/65
Abstract: Raman spectroscopic analyzer including: a beam-casting unit 3 for receiving a light beam generated by a light source and for converging the light beam on a predetermined position in a perpendicular direction to the longitudinal direction of a measurement chamber through which a liquid sample is passed; and a light-receiving unit placed at a distance in the longitudinal direction from the predetermined position, for receiving scattered light emitted from the fluid sample. Among the scattered light which enters the light-receiving unit, the portion which enters this unit after being reflected by the inner wall surface opposite to this unit is eliminated, so that the amount of noise in the Raman spectroscopic measurement is considerably reduced.
Abstract translation: 拉曼光谱分析仪,包括:光束铸造单元3,用于接收由光源产生的光束,并且用于将光束会聚在与通过液体样品的测量室的纵向方向垂直的预定位置上 ; 以及光接收单元,其从所述预定位置沿所述纵向方向放置,用于接收从所述流体样本发射的散射光。 在进入光接收单元的散射光中,消除了在被与该单元相对的内壁面反射之后进入该单元的部分,使得拉曼光谱测量中的噪声量显着降低。
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公开(公告)号:US09335209B2
公开(公告)日:2016-05-10
申请号:US14628642
申请日:2015-02-23
Applicant: Seiko Epson Corporation
Inventor: Yasushi Matsuno , Tsugio Gomi
IPC: G02B5/20 , G01J1/04 , G01J1/02 , G01J3/02 , G01J3/26 , G01J3/50 , G02B5/28 , G02B26/00 , G01J1/32
CPC classification number: G02B26/001 , G01J1/0214 , G01J1/0271 , G01J1/0488 , G01J1/32 , G01J3/0291 , G01J3/26 , G01J3/506 , G02B5/284
Abstract: An optical module includes a circuit substrate that has a concave portion and a flat surface, an optical sensor that is disposed inside a space, and an optical filter device that has a base which accommodates a variable wavelength interference filter and has a light-through hole through which light emitted from the variable wavelength interference filter passes and a first glass member which is disposed in the light-through hole. The first glass member is positioned inside the space. The base is bonded to the flat surface. The distance between the first glass member and the optical sensor is set to a distance at which light emitted from the variable wavelength interference filter does not interfere between the first glass member and the optical sensor.
Abstract translation: 光学模块包括具有凹部和平坦表面的电路基板,设置在空间内的光学传感器,以及具有容纳可变波长干涉滤光器的基部的光学滤波器装置,具有通孔 从可变波长干涉滤光器发出的光通过其穿过,以及设置在该光通孔中的第一玻璃构件。 第一个玻璃构件位于空间内。 底座粘合到平面上。 将第一玻璃构件和光学传感器之间的距离设定为从可变波长干涉滤光器发射的光不会干涉第一玻璃构件和光学传感器之间的距离。
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公开(公告)号:US20160120450A1
公开(公告)日:2016-05-05
申请号:US14926174
申请日:2015-10-29
Applicant: Seiko Epson Corporation
Inventor: Kazunori SAKURAI
IPC: A61B5/1455 , A61B5/00 , G01J3/02
CPC classification number: A61B5/14552 , A61B5/6831 , A61B5/6833 , A61B2560/0406 , A61B2562/0233 , A61B2562/185 , G01J3/0202 , G01J3/0205 , G01J3/0259 , G01J3/0291 , G01J3/26 , G01N21/01 , G01N21/31 , G01N2201/0227 , G01N2201/064
Abstract: A biological body inspection apparatus includes a measurement module that acquires an amount of light having a wavelength under measurement contained in light incident on the measurement module and an enclosure that accommodates the measurement module and has a window that transmits light traveling toward the measurement module. An adhesive member is provided on a surface of the enclosure at least in an area thereof that surrounds the window. The adhesive member has a light blocking section that is located in an area outside the window and surrounds the window in a plan view in the direction along the optical axis of the light traveling toward the measurement module and blocks light that belongs to a measurement wavelength region within which at least the wavelength under measurement is present.
Abstract translation: 生物体检查装置包括测量模块,该测量模块获取入射在测量模块上的光所包含的测量波长的光量,以及容纳测量模块的外壳,并且具有透射朝向测量模块传播的光的窗口。 至少在其围绕窗户的区域中,在外壳的表面上设置粘合构件。 所述粘接部件具有遮光部,所述遮光部位于所述窗外部的区域中,并且沿着朝向所述测量模块行进的所述光的光轴方向的俯视图中包围所述窗,并且遮挡属于所述测量波长区域的光 其中至少存在测量波长。
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公开(公告)号:US20160116337A1
公开(公告)日:2016-04-28
申请号:US14985722
申请日:2015-12-31
Applicant: Pendar Technologies, LLC
Inventor: Mark F. Witinski , Laurent Diehl , Christian Pfluegl
CPC classification number: G01J3/42 , G01J3/0208 , G01J3/0286 , G01J3/0291 , G01J3/10 , G01J2003/102
Abstract: A spectroscopy system includes an array of quantum cascade lasers (QCLs) that emits an array of non-coincident laser beams. A lens array coupled to the QCL array substantially collimates the laser beams, which propagate along parallel optical axes towards a sample. The beams remain substantially collimated over the lens array's working distance, but may diverge when propagating over longer distances. The collimated, parallel beams may be directed to/through the sample, which may be within a sample cell, flow cell, multipass spectroscopic absorption cell, or other suitable holder. Alternatively, the beams may be focused to a point on, near, or within the target using a telescope or other suitable optical element(s). When focused, however, the beams remain non-coincident; they simply intersect at the focal point. The target transmits, reflects, and/or scatters this incident light to a detector, which transduces the detected radiation into an electrical signal representative of the target's absorption or emission spectrum.
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