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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.
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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.
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公开(公告)号:US11771325B2
公开(公告)日:2023-10-03
申请号:US17301997
申请日:2021-04-21
Applicant: SYNAPTIVE MEDICAL INC.
Inventor: Ze Shan Yao , Piotr Kuchnio , Michael Frank Gunter Wood , Tammy Kee-Wai Lee , Yanhui Bai , Michael Peter Bulk , Christopher Thomas Jamieson
IPC: A61B5/00 , A61B34/20 , A61B5/026 , G01J3/443 , A61B90/00 , A61B5/06 , G01J3/28 , G01J3/10 , G01J3/02 , A61B90/20 , A61B90/30 , A61B17/34
CPC classification number: A61B5/0075 , A61B5/0042 , A61B5/0071 , A61B5/0077 , A61B5/0082 , A61B5/0084 , A61B5/026 , A61B5/061 , A61B5/748 , A61B5/7425 , A61B34/20 , A61B90/361 , G01J3/0248 , G01J3/10 , G01J3/2803 , G01J3/2823 , G01J3/443 , A61B5/0261 , A61B5/725 , A61B17/34 , A61B90/20 , A61B2034/2055 , A61B2090/309 , A61B2562/0233 , A61B2562/0242 , G01J2003/106 , G01J2003/2826
Abstract: A multispectral synchronized imaging system is provided. A multispectral light source of the system comprises: blue, green and red LEDs, and one or more non-visible light sources, each being independently addressable and configured to emit, in a sequence: at least visible white light, and non-visible light in one or more given non-visible frequency ranges. The system further comprises a camera and an optical filter arranged to filter light received at the camera, by: transmitting visible light from the LEDs; filter out non-visible light from the non-visible light sources; and otherwise transmit excited light emitted by a tissue sample excited by non-visible light. Images acquired by the camera are output to a display device. A control unit synchronizes acquisition of respective images at the camera for each of blue light, green light, visible white light, and excited light received at the camera, as reflected by the tissue sample.
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公开(公告)号:US20180328786A1
公开(公告)日:2018-11-15
申请号:US15983019
申请日:2018-05-17
Applicant: CALIFORNIA INSTITUTE OF TECHNOLOGY
Inventor: James L. LAMBERT
CPC classification number: G01J3/44 , G01J3/0208 , G01J3/0224 , G01J3/0227 , G01J3/0237 , G01J3/0248 , G01J3/10 , G01J3/18 , G01J3/28 , G01J3/2823 , G01J3/4406 , G01J2003/102
Abstract: Methods and systems for Raman spectroscopy and context imaging are disclosed. One or two lasers can be used to excite Raman scattering in a sample, while a plurality of LEDs can illuminate the sample at a different wavelength. The LED light is collected by a lenslet array in order to enable a high depth of field. Focusing of the image can be carried out at specific points of the image by processing the light collected by the lenslet array.
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公开(公告)号:US09927300B2
公开(公告)日:2018-03-27
申请号:US15439091
申请日:2017-02-22
Applicant: Michael Golub , Amir Averbuch , Menachem Nathan
Inventor: Michael Golub , Amir Averbuch , Menachem Nathan
CPC classification number: H04N5/23232 , G01J3/0208 , G01J3/0229 , G01J3/0248 , G01J3/18 , G01J3/2823 , G01J3/36 , G02B5/1814 , G02B5/1842 , G06T5/20 , G06T7/33 , G06T7/337 , G06T11/60 , G06T2207/20221 , H04N5/2254 , H04N5/2258 , H04N5/23238 , H04N5/23296 , H04N5/332 , H04N9/045 , H04N9/09 , H04N9/097 , H04N9/735 , H04N2209/045
Abstract: Snapshot spectral imagers comprise an imaging lens, a dispersed image sensor and a restricted isometry property (RIP) diffuser inserted in the optical path between the source image and the image sensor. The imagers are used to obtain a plurality of spectral images of the source object in different spectral bands in a single shot. In some embodiments, the RIP diffuser is one dimensional. An optional disperser may be added in the optical path, to provide further dispersion at the image sensor. In some embodiments, all imager components except the RIP diffuser may be part of a digital camera, with the RIP diffuser added externally. In some embodiments, the RIP diffuser may be included internally in a digital camera.
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公开(公告)号:US09876952B2
公开(公告)日:2018-01-23
申请号:US15375090
申请日:2016-12-11
Applicant: Corephotonics Ltd.
Inventor: Gal Shabtay , Noy Cohen , Oded Gigushinski , Ephraim Goldenberg
CPC classification number: H04N5/23232 , G01J3/0208 , G01J3/0229 , G01J3/0248 , G01J3/18 , G01J3/2823 , G01J3/36 , G02B5/1814 , G02B5/1842 , G06T5/20 , G06T7/33 , G06T7/337 , G06T11/60 , G06T2207/20221 , H04N5/2254 , H04N5/2258 , H04N5/23238 , H04N5/23296 , H04N5/332 , H04N9/045 , H04N9/09 , H04N9/097 , H04N9/735 , H04N2209/045
Abstract: A multi-aperture imaging system comprising a first camera with a first sensor that captures a first image and a second camera with a second sensor that captures a second image, the two cameras having either identical or different FOVs. The first sensor may have a standard color filter array (CFA) covering one sensor section and a non-standard color CFA covering another. The second sensor may have either Clear or standard CFA covered sections. Either image may be chosen to be a primary or an auxiliary image, based on a zoom factor. An output image with a point of view determined by the primary image is obtained by registering the auxiliary image to the primary image.
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公开(公告)号:US09804029B2
公开(公告)日:2017-10-31
申请号:US15120792
申请日:2015-01-16
Applicant: HITACHI HIGH-TECHNOLOGIES CORPORATION
Inventor: Tsuyoshi Sonehara , Hiromi Kusaka , Akira Fujii , Shuhei Yamamoto , Takeshi Ooura , Michiru Fujioka
IPC: G01J3/30 , G01J3/42 , G01J3/24 , G01J3/44 , G02B7/28 , G02B7/32 , G01N21/65 , G02B21/36 , G01N21/64 , G01J3/02 , G01J3/10 , G02B21/00 , G02B21/16 , G02B21/24 , G02B27/14
CPC classification number: G01J3/44 , G01J3/0208 , G01J3/021 , G01J3/0229 , G01J3/0248 , G01J3/10 , G01J3/4406 , G01N21/6458 , G01N21/65 , G02B7/28 , G02B7/32 , G02B21/0004 , G02B21/16 , G02B21/244 , G02B21/36 , G02B21/365 , G02B27/141
Abstract: With a microspectroscopy device provided with an objective lens with a high numerical aperture, a defocus arises from thermal drift, etc., necessitating auto-focusing. Conventional auto-focus based on through-focus image acquisition takes time, and thus, it cannot be applied to continuous measurement over a long time wherein high-speed sampling is carried out. The present invention addresses this problem by having a defocus-sensing beam that has either defocus or astigmatism fall incident on the objective lens. Since how the image of the spot of the beam for defocus sensing blurs differs depending on the orientation of the defocus, real-time detection of the amount and orientation of defocus becomes possible, and high-speed realtime auto-focus becomes possible.
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公开(公告)号:US09784615B1
公开(公告)日:2017-10-10
申请号:US15362108
申请日:2016-11-28
Applicant: BaySpec, Inc.
Inventor: Guocai Shu , Shu Zhang , William Yang
CPC classification number: G01J3/0289 , G01J3/0248 , G01J3/0294 , G01J3/2803 , G01J3/2823 , G01J2003/283
Abstract: Systems for adjusting for irregular movement during spectral imaging are provided herein. Exemplary systems include: a spectrograph measuring a plurality of spectrographic data sets; a camera capturing images, a processor communicatively coupled to the spectrograph and the camera; and a memory coupled to the processor, the memory storing instructions executable by the processor to perform a method comprising: receiving a plurality of spectrographs for a series of respective locations and the images corresponding to the respective locations; generating a continuous image using the images; identifying a respective corresponding position in the continuous image for each spectrograph, such that each spectrograph is a measurement of the respective position; and associating each spectrograph with the respective position.
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公开(公告)号:US20170209050A1
公开(公告)日:2017-07-27
申请号:US15416876
申请日:2017-01-26
Applicant: Novadaq Technologies Inc.
Inventor: John Josef Paul FENGLER , Robert Anthony STEAD
CPC classification number: A61B5/0071 , A61B1/00186 , A61B1/043 , A61B1/051 , A61B1/0638 , A61B1/0684 , A61B5/0035 , A61B5/0084 , G01J1/00 , G01J1/58 , G01J3/0205 , G01J3/0208 , G01J3/021 , G01J3/0248 , G01J3/10 , G01J3/36 , G01J3/4406 , G02B21/16 , G02B27/1013 , H04N5/2256 , H04N5/23245 , H04N5/2354 , H04N5/238 , H04N5/332 , H04N9/045 , H04N9/097 , H04N13/204 , H04N2209/049
Abstract: A fluorescence imaging system for imaging an object, the system includes a white light provider that emits white light, an excitation light provider that emits excitation light in a plurality of excitation wavebands for causing the object to emit fluorescent light, a component that directs the white light and excitation light to the object and collects reflected white light and emitted fluorescent light from the object, a filter that blocks light in the excitation wavebands and transmits at least a portion of the reflected white light and fluorescent light, and an image sensor assembly that receives the transmitted reflected white light and the fluorescent light.
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公开(公告)号:US20170195586A1
公开(公告)日:2017-07-06
申请号:US15389057
申请日:2016-12-22
Applicant: IMEC VZW
Inventor: Jonathan Borremans , Andy Lambrechts , Jerome Baron
CPC classification number: H04N5/332 , G01C3/08 , G01J3/0237 , G01J3/0248 , G01J3/0278 , G01J3/28 , G01J3/2823 , G01J2003/2826 , G06T7/90 , G06T2207/10016 , H04N5/23212 , H04N5/23222 , H04N5/23293
Abstract: A user device including a camera, a spectrometer module, and a processing unit is disclosed. In one aspect, the camera is adapted to acquire at least one image of a scenery which falls within a field of view of the camera. The spectrometer module is adapted to acquire spectral information from a region within the scenery which region falls within a field of view of the spectrometer module. The processing unit is adapted to determine, based on information relating the field of view of the spectrometer module to the field of view of the camera, a spectrometer module target area, within the at least one image, corresponding to the region. The processing unit is adapted to output display data to a screen of the user device for providing an indication of the target area on the display.
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