公开(公告)号：US09797876B2

公开(公告)日：2017-10-24

申请号：US15357225

申请日：2016-11-21

Applicant: OMNI MEDSCI, INC.

Inventor： Mohammed N. Islam

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

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 ,  G06F19/00 ,  G16H40/67 ,  H01S3/0092 ,  H01S3/06758 ,  H01S3/302

Abstract: A measurement system includes semiconductor light sources generating an input beam, optical amplifiers receiving the input beam and delivering an intermediate beam, and fused silica fibers with core diameters less than 400 microns receiving and delivering the intermediate beam to the fibers forming a first optical beam. A nonlinear element receives the first optical beam and broadens the spectrum to at least 10 nm through a nonlinear effect to form the output optical beam which includes a near-infrared wavelength of 700-2500 nm. A measurement apparatus is configured to receive the output optical beam and deliver it to a sample to generate a spectroscopy output beam. A receiver receives the spectroscopy output beam having a bandwidth of at least 10 nm and processes the beam to generate an output signal, wherein the light source and the receiver are remote from the sample, and wherein the sample comprises plastics or food industry goods.

公开(公告)号：US09778107B2

公开(公告)日：2017-10-03

申请号：US15075187

申请日：2016-03-20

Applicant: Zhilin Hu

Inventor： Zhilin Hu

IPC: G01J3/28 ,  G01J3/18 ,  G02B5/18 ,  G02B1/14 ,  G02B5/04 ,  G01J3/14 ,  G01J3/02 ,  G01J3/12

CPC classification number: G01J3/18 ,  G01J3/0208 ,  G01J3/0218 ,  G01J3/14 ,  G01J3/28 ,  G01J2003/1208 ,  G02B1/14 ,  G02B5/04 ,  G02B5/1814

Abstract: A linear frequency domain grating and a multiband spectrometer having the same. The linear frequency domain grating includes a dispersive optical element and a diffractive optical element being substantially in contact with the dispersive optical element or being substantially integrated with the dispersive optical element, configured to receive a beam of incident light along an incident optical path, and diffract and disperse it into its constituent spectrum of frequencies of the light that is output from the dispersive optical element along an output optical path, such that the output light has a spatial distribution on a focal plane in the output optical path that is a linear function of the frequency. The linear frequency domain grating is a transmissive-type grating or a reflective-type grating, depending on whether the incident optical path and the output optical path are in different sides or the same side of the diffractive optical element.

公开(公告)号：US09757040B2

公开(公告)日：2017-09-12

申请号：US15357136

申请日：2016-11-21

Applicant: OMNI MEDSCI, INC.

Inventor： Mohammed N. Islam

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

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 ,  G06F19/00 ,  G16H40/67 ,  H01S3/0092 ,  H01S3/06758 ,  H01S3/302

Abstract: A wearable device for use with a smart phone or tablet includes a measurement device having a plurality of LEDs generating a near-infrared input optical beam that measures physiological parameters. The measurement device includes lenses configured to receive and to deliver the input beam to skin which reflects the beam. The measurement device includes a reflective surface configured to receive and redirect the light from the skin, and a receiver configured to receive the reflected beam. The light source is configured to increase a signal-to-noise ratio of the input beam reflected from the skin by increasing the light intensity from the LEDs and modulation of the LEDs. The measurement device is configured to generate an output signal representing a non-invasive measurement on blood contained within the skin. The wearable device is configured to wirelessly communicate with the smart phone or tablet which receives and processes the output signal.

公开(公告)号：US20170248567A1

公开(公告)日：2017-08-31

申请号：US15594053

申请日：2017-05-12

Applicant: OMNI MEDSCI, INC.

Inventor： Mohammed N. ISLAM

IPC: G01N33/15 ,  A61B5/1455 ,  A61B5/145 ,  G01J3/10 ,  G01J3/28 ,  G01N33/02 ,  G01N21/3563 ,  G01N21/359 ,  G01N21/88 ,  G01J3/14 ,  G01N33/44 ,  A61B5/00 ,  G01J3/453

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 ,  G06F19/00 ,  G16H40/67 ,  H01S3/0092 ,  H01S3/06758 ,  H01S3/302 ,  Y02A90/26

Abstract: A wearable device for measuring physiological parameters includes a light source having a plurality of semiconductor light emitting diodes (LEDs) each configured to generate an output optical beam, wherein at least a portion of the one or more optical beam wavelengths is a near-infrared wavelength. The light source is configured to increase signal-to-noise ratio by increasing light intensity for at least one of the LEDs and by increasing a pulse rate of at least one of the LEDs. A lens is configured to receive the output optical beam and to deliver a lens output beam to tissue. A detection system generates an output signal in response to the lens output beam reflected from the tissue, wherein the detection system is configured to be synchronized to the light source, and is located a different distance from a first one of the LEDs than a second one of the LEDs.

公开(公告)号：US20170067780A1

公开(公告)日：2017-03-09

申请号：US15122530

申请日：2015-02-06

Applicant: MICRO-EPSILON Optronic GmbH

Inventor： Tobias Otto

IPC: G01J3/14 ,  G01J3/18 ,  G01J3/22 ,  G01J3/02

CPC classification number: G01J3/14 ,  G01J3/0208 ,  G01J3/0256 ,  G01J3/18 ,  G01J3/22 ,  G01J3/2803 ,  G01J2003/1208

Abstract: The invention relates to a spectrometer comprising a combination of at least one grid (1) and at least one prism (2), characterised in that total reflexion is used to produce a compact spectrometer in at least one prism (2).

Abstract translation: 本发明涉及一种包括至少一个格栅（1）和至少一个棱镜（2）的组合的光谱仪，其特征在于，全反射用于在至少一个棱镜（2）中产生紧凑的光谱仪。

公开(公告)号：US09500634B2

公开(公告)日：2016-11-22

申请号：US14650981

申请日：2013-12-17

Applicant: OMNI MEDSCI, INC.

Inventor： Mohammed N. Islam

IPC: G01J3/00 ,  G01N33/15 ,  A61B5/1455 ,  A61B5/00 ,  G01J3/10 ,  G01J3/28 ,  G01J3/453 ,  G01N21/359 ,  A61B5/145 ,  G01N33/49 ,  H01S3/30 ,  G01J3/14 ,  G01J3/18

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 ,  G06F19/00 ,  G16H40/67 ,  H01S3/0092 ,  H01S3/06758 ,  H01S3/302

Abstract: A system and method for using near-infrared or short-wave infrared (SWIR) light sources between approximately 1.4-1.8 microns, 2-2.5 microns, 1.4-2.4 microns, 1-1.8 microns for active remote sensing or hyper-spectral imaging for detection of natural gas leaks or exploration sense the presence of hydro-carbon gases such as methane and ethane. Most hydro-carbons (gases, liquids and solids) exhibit spectral features in the SWIR, which may also coincide with atmospheric transmission windows (e.g., approximately 1.4-1.8 microns or 2-2.5 microns). Active remote sensing or hyper-spectral imaging systems may include a fiber-based super-continuum laser and a detection system and may reside on an aircraft, vehicle, handheld, or stationary platform. Super-continuum sources may emit light in the near-infrared or SWIR. An imaging spectrometer or a gas-filter correlation radiometer may be used to identify substances or materials such as oil spills, geology and mineralogy, vegetation, greenhouse gases, construction materials, plastics, explosives, fertilizers, paints, or drugs.

Abstract translation: 一种使用近红外或短波红外（SWIR）光源的系统和方法，用于主动遥感或超光谱成像，大约为1.4-1.8微米，2-2.5微米，1.4-2.4微米，1-1.8微米 天然气泄漏或勘探的检测意识到甲烷和乙烷等氢碳气体的存在。 大多数碳氢化合物（气体，液体和固体）在SWIR中表现出光谱特征，这也可能与大气透射窗口（例如，约1.4-1.8微米或2-2.5微米）重合。 主动遥感或超光谱成像系统可以包括基于光纤的超连续激光器和检测系统，并且可以驻留在飞机，车辆，手持或固定平台上。 超连续光源可能在近红外或SWIR发光。 成像光谱仪或气体过滤器相关辐射计可用于识别物质或材料，如漏油，地质和矿物学，植被，温室气体，建筑材料，塑料，爆炸物，肥料，油漆或药物。

公开(公告)号：US20160327476A1

公开(公告)日：2016-11-10

申请号：US15212549

申请日：2016-07-18

Applicant: OMNI MEDSCI, INC.

Inventor： Mohammed N. ISLAM

IPC: G01N21/359 ,  A61B5/145 ,  A61B5/00 ,  G01N33/49 ,  A61B5/1455

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 ,  G06F19/00 ,  G16H40/67 ,  H01S3/0092 ,  H01S3/06758 ,  H01S3/302

Abstract: A wearable device for use with a smart phone or tablet includes a measurement device having a light source with a plurality of light emitting diodes (LEDs) for measuring physiological parameters and configured to generate an optical beam with wavelengths including a near-infrared wavelength between 700 and 2500 nanometers. The measurement device includes lenses configured to deliver the optical beam to a sample of skin or tissue, which reflects the optical beam to a receiver located a first distance from one of the LEDs and a different distance from another of the LEDs, and is also configured to generate an output signal representing a non-invasive measurement on blood contained within the sample. The wearable device is configured to communicate with the smart phone or tablet, which receives, processes, stores and displays the output signal with the processed output signal configured to be transmitted over a wireless transmission link.

Abstract translation: 用于智能手机或平板电脑的可穿戴式装置包括具有光源的测量装置，该光源具有用于测量生理参数的多个发光二极管（LED），并且被配置为产生波长包括近红外波长在700 和2500纳米。 测量装置包括被配置为将光束传送到皮肤或组织的样本的透镜，其将光束反射到位于距离其中一个LED的第一距离并且距离另一个LED不同距离的接收器，并且还被配置 以产生代表样品内包含的血液的非侵入性测量的输出信号。 可穿戴设备被配置为与智能电话或平板电脑进行通信，智能电话或平板电脑接收，处理，存储和显示输出信号，处理后的输出信号被配置为通过无线传输链路发送。

公开(公告)号：US20160282180A1

公开(公告)日：2016-09-29

申请号：US15075187

申请日：2016-03-20

Applicant: Zhilin Hu

Inventor： Zhilin Hu

IPC: G01J3/18 ,  G02B1/14 ,  G01J3/28 ,  G01J3/14 ,  G01J3/02 ,  G02B5/18 ,  G02B5/04

CPC classification number: G01J3/18 ,  G01J3/0208 ,  G01J3/0218 ,  G01J3/14 ,  G01J3/28 ,  G01J2003/1208 ,  G02B1/14 ,  G02B5/04 ,  G02B5/1814

Abstract: A linear frequency domain grating and a multiband spectrometer having the same. The linear frequency domain grating includes a dispersive optical element and a diffractive optical element being substantially in contact with the dispersive optical element or being substantially integrated with the dispersive optical element, configured to receive a beam of incident light along an incident optical path, and diffract and disperse it into its constituent spectrum of frequencies of the light that is output from the dispersive optical element along an output optical path, such that the output light has a spatial distribution on a focal plane in the output optical path that is a linear function of the frequency. The linear frequency domain grating is a transmissive-type grating or a reflective-type grating, depending on whether the incident optical path and the output optical path are in different sides or the same side of the diffractive optical element.

Abstract translation: 线性频域光栅和具有相同光谱的多频带光谱仪。 线性频域光栅包括色散光学元件和衍射光学元件，该衍射光学元件基本上与色散光学元件接触或者与分散光学元件基本上集成，被配置为沿着入射光路接收入射光束，并衍射 并将其分散到其沿着输出光路从色散光学元件输出的光的频率的组成谱中，使得输出光在输出光路中的焦平面上具有作为线性函数的线性函数的空间分布 频率。 线性频域光栅是透射型光栅或反射型光栅，取决于入射光路和输出光路是否位于衍射光学元件的不同侧或同一侧。

公开(公告)号：US20150369728A1

公开(公告)日：2015-12-24

申请号：US14842095

申请日：2015-09-01

Applicant: LIFE TECHNOLOGIES CORPORATION

Inventor： Dar BAHATT ,  Chirag Patel ,  Roy H. Tan ,  Derek K. Prothro

IPC: G01N21/31 ,  G01J3/28 ,  G01J3/12

CPC classification number: G01N21/31 ,  G01J3/10 ,  G01J3/12 ,  G01J3/18 ,  G01J3/189 ,  G01J3/2803 ,  G01J3/2823 ,  G01J3/4406 ,  G01J2003/1204 ,  G01J2003/1208 ,  G01J2003/1213 ,  G01J2003/1226 ,  G01N21/0332 ,  G01N21/253 ,  G01N21/6428 ,  G01N21/6452 ,  G01N21/6456 ,  G01N21/76 ,  G01N2021/6421 ,  G01N2021/6432 ,  G01N2201/06113 ,  G01N2201/0621 ,  G01N2201/0697

Abstract: Systems, including methods, apparatus, and algorithms, for spectrally imaging a two-dimensional array of samples.

Abstract translation: 用于对二维样本阵列进行光谱成像的系统，包括方法，装置和算法。

公开(公告)号：US20150305658A1

公开(公告)日：2015-10-29

申请号：US14650897

申请日：2013-12-17

Applicant: OMNI MEDSCI. INC.

Inventor： Mohammed N. ISLAM

IPC: A61B5/1455 ,  A61B5/00 ,  A61B5/145

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 ,  G06F19/00 ,  G16H40/67 ,  H01S3/0092 ,  H01S3/06758 ,  H01S3/302

Abstract: Non-invasive monitoring of blood constituents such as glucose, ketones, or hemoglobin A1c may be accomplished using near-infrared or short-wave infrared (SWIR) light sources through absorbance, diffuse reflection, or transmission spectroscopy. As an example, hydro-carbon related substances such as glucose or ketones have distinct spectral features in the SWIR between approximately 1500 and 2500 nm. An SWIR super-continuum laser based on laser diodes and fiber optics may be used as the light source for the non-invasive monitoring. Light may be transmitted or reflected through a tooth, since an intact tooth and its enamel and dentine may be nearly transparent in the SWIR. Blood constituents or analytes within the capillaries in the dental pulp may be detected. The non-invasive monitoring device may communicate with a device such as a smart phone or tablet, which may transmit a signal related to the measurement to the cloud with cloud-based value-added services.

Abstract translation: 通过吸收，漫反射或透射光谱可以使用近红外或短波红外（SWIR）光源实现对血液成分如葡萄糖，酮或血红蛋白A1c的非侵入性监测。 作为示例，水 - 碳相关物质如葡萄糖或酮在SWIR中在约1500和2500nm之间具有不同的光谱特征。 可以使用基于激光二极管和光纤的SWIR超连续激光器作为非侵入性监测的光源。 光可以通过牙齿传播或反射，因为完整的牙齿及其牙釉质和牙质在SWIR中可能几乎是透明的。 可以检测牙髓中毛细血管内的血液成分或分析物。 非侵入式监测设备可以与诸如智能电话或平板电脑的设备进行通信，智能电话或平板电脑可以使用基于云的增值业务将与测量相关的信号传输到云。