公开(公告)号：US20180266887A1

公开(公告)日：2018-09-20

申请号：US15987819

申请日：2018-05-23

Applicant: FLIR Systems, Inc.

Inventor： Jeffrey D. Frank ,  Theodore R. Hoelter ,  Nicholas Högasten ,  Austin A. Richards ,  Michael Kent ,  Julie R. Moreira ,  Pierre Boulanger ,  Raymond Valdes ,  Jonathan Li

IPC: G01J5/06 ,  B64C39/02 ,  G08G5/00 ,  G01J5/00 ,  G03B15/00 ,  H02S50/00 ,  H04N5/33 ,  G06K9/00

CPC classification number: G01J5/00 ,  B64C39/024 ,  B64C2201/123 ,  B64C2201/127 ,  B64C2201/141 ,  B64C2201/146 ,  G01J5/007 ,  G01J5/0265 ,  G01J5/06 ,  G01J5/061 ,  G01J2005/0048 ,  G01J2005/0055 ,  G01J2005/0077 ,  G01J2005/068 ,  G03B15/006 ,  G06K9/0063 ,  G08G5/0091 ,  H02J4/00 ,  H02S50/00 ,  H02S50/15 ,  H04N5/2351 ,  H04N5/243 ,  H04N5/33 ,  H04N7/185 ,  H04W4/046 ,  H04W84/18

Abstract: Flight based infrared imaging systems and related techniques, and in particular UAS based thermal imaging systems, are provided to improve the monitoring capabilities of such systems over conventional infrared monitoring systems. An infrared imaging system is configured to compensate for various environmental effects (e.g., position and/or strength of the sun, atmospheric effects) to provide high resolution and accuracy radiometric measurements of targets imaged by the infrared imaging system. An infrared imaging system is alternatively configured to monitor and determine environmental conditions, modify data received from infrared imaging systems and other systems, modify flight paths and other commands, and/or create a representation of the environment.

公开(公告)号：US20170284869A1

公开(公告)日：2017-10-05

申请号：US15088833

申请日：2016-04-01

Applicant: LumaSense Technologies Holdings, Inc.

Inventor： Tim Patrick Dubbs ,  John Leonard Shaver ,  Kreg James Kelley

IPC: G01J5/50 ,  G06K9/32 ,  G06K9/20 ,  H04N5/33 ,  H04N5/247

CPC classification number: G01J5/505 ,  G01J5/0044 ,  G01J5/089 ,  G01J2005/0048 ,  G01J2005/0051 ,  G01J2005/0055 ,  G01J2005/0077 ,  G06K9/2081 ,  G06K9/3233 ,  G06K9/4661 ,  H04N5/247 ,  H04N5/33

Abstract: A method for measuring furnace temperatures. The method includes obtaining radiance measurements from a plurality of regions of interest (ROIs) using a plurality of thermal imaging cameras, and measuring a surface temperature using a radiance measurement obtained from an ROI selected from the plurality of ROIs. Measuring the surface temperature includes determining an effective background radiance affecting the selected ROI using radiance measurements obtained from ROIs different from the selected ROI, obtaining a compensated radiance by removing the effective background radiance from the radiance measurement obtained from the selected ROI, and converting the compensated radiance to the measured surface temperature.

公开(公告)号：US20040210391A1

公开(公告)日：2004-10-21

申请号：US10819621

申请日：2004-04-07

Inventor： Marc A. Kolodner ,  Patricia K. Murphy ,  Edward E. Hume

IPC: G06F169/00

CPC classification number: G06K9/3241 ,  G01J3/28 ,  G01J3/2823 ,  G01J5/007 ,  G01J2003/2826 ,  G01J2005/0055

Abstract: A method and structure that inputs atmospheric forecast information from the atmospheric forecast database based on current, real time atmospheric measurements. The hyperspectral detection processing unit also inputs at least one selected reflectance library from the reflectance library database, and data collection and sensor parameters from the sensor. With this information, the hyperspectral detection processing unit employs a model to produce at least one mission radiance library during the mission planning phase. Then, during the actual mission execution, the sensor is used to collect the hyperspectral data and the comparator can immediately compare the hyperspectral data to the mission radiance library to identify features and/or targets.

Abstract translation: 一种基于当前实时大气测量从大气预报数据库输入大气预报信息的方法和结构。 高光谱检测处理单元还从反射谱库数据库输入至少一个选定的反射谱库，以及来自传感器的数据收集和传感器参数。 利用这些信息，高光谱检测处理单元在任务规划阶段使用一个模型来生成至少一个任务辐射库。 然后，在实际任务执行期间，传感器用于收集高光谱数据，比较器可以立即将高光谱数据与任务辐射库进行比较，以识别特征和/或目标。

公开(公告)号：US20180266886A1

公开(公告)日：2018-09-20

申请号：US15984176

申请日：2018-05-18

Applicant: FLIR Systems, Inc.

Inventor： Jeffrey D. Frank ,  Michael Kent ,  Anna-Karin Lindblom ,  Lei Bennett ,  Andrew C. Teich

IPC: G01J5/06 ,  G01J5/00 ,  H02S50/00 ,  H04N5/33 ,  H04N5/235 ,  H04N5/243

CPC classification number: G01J5/00 ,  B64C39/024 ,  B64C2201/123 ,  B64C2201/127 ,  B64C2201/141 ,  B64C2201/146 ,  G01J5/007 ,  G01J5/0265 ,  G01J5/06 ,  G01J5/061 ,  G01J2005/0048 ,  G01J2005/0055 ,  G01J2005/0077 ,  G01J2005/068 ,  G03B15/006 ,  G06K9/0063 ,  G08G5/0091 ,  H02J4/00 ,  H02S50/00 ,  H02S50/15 ,  H04N5/2351 ,  H04N5/243 ,  H04N5/33 ,  H04N7/185 ,  H04W4/046 ,  H04W84/18

Abstract: Flight based infrared imaging systems and related techniques, and in particular UAS based thermal imaging systems, are provided to improve the monitoring capabilities of such systems over conventional infrared monitoring systems. An infrared imaging system is configured to compensate for various environmental effects (e.g., position and/or strength of the sun, atmospheric effects) to provide high resolution and accuracy radiometric measurements of targets imaged by the infrared imaging system. An infrared imaging system is alternatively configured to monitor regulatory limitations on operation of the infrared imaging system and adjust and/or disable operation of the infrared imaging systems accordingly.

公开(公告)号：US20150036718A1

公开(公告)日：2015-02-05

申请号：US13954855

申请日：2013-07-30

Applicant: King Abdul Aziz City for Science and Technology (KACST)

Inventor： Yaser A. Hafez ,  Hamoud H. Alharbi

IPC: G01K11/00

CPC classification number: G01J5/10 ,  G01J2005/0055 ,  G01J2005/0077

Abstract: The invention provides a method for detecting thermal emissions from the new moon, wherein the new moon is positioned at an angle of less than about 5 degrees from the Sun. The invention utilizes a radio telescope, wherein a side-lobe level of the radio telescope is less than about −20 dB, wherein an effective telescope diameter of the radio telescope depends on a wavelength of operation. Further, a FWHM beamwidth of the radio telescope is less than about 0.5 degree. The method comprises setting one or more of the operating frequency of the radio telescope to a value selected from the range of about 1 GHz and about 100 GHz, and the operating bandwidth of the radio telescope to a value selected from the range of about 1 GHz and about 10 GHz. In addition, the method comprises collecting at least one observation from the radio telescope.

Abstract translation: 本发明提供一种用于检测来自新月的热量排放的方法，其中新月与太阳的距离小于约5度。 本发明利用射电望远镜，其中射电望远镜的旁瓣电平小于约-20dB，其中无线电望远镜的有效望远镜直径取决于操作波长。 此外，无线电望远镜的FWHM波束宽度小于约0.5度。 该方法包括将无线电望远镜的一个或多个操作频率设置为从约1GHz和约100GHz的范围内选择的值，以及将无线电望远镜的操作带宽设置为从约1GHz 约10 GHz。 此外，该方法包括从无线电望远镜收集至少一个观测值。

公开(公告)号：US20120310578A1

公开(公告)日：2012-12-06

申请号：US13134264

申请日：2011-06-03

Applicant: Fredrick S. Solheim

Inventor： Fredrick S. Solheim

IPC: G01J5/00 ,  G06F19/00

CPC classification number: G01K1/00 ,  G01J5/007 ,  G01J2005/0055

Abstract: Apparatus and methods are disclosed for enhancing data accuracy of a noncontact infrared thermometer. One method includes determining dry atmospheric constituency and water vapor absorption coefficients across the infrared thermometers spectral bandpass and implementing the coefficients in processing with site-based atmospheric temperature and water vapor density profile and pressure measurements to provide corrected target temperature data compensating for contamination in said raw data due to said intervening atmosphere. The method is particularly well adapted for use in correcting data from less expensive but also less accurate wideband infrared thermometers.

Abstract translation: 公开了用于提高非接触式红外线温度计的数据精度的装置和方法。 一种方法包括确定跨红外温度计光谱带通的干燥大气区域和水蒸汽吸收系数，并在基于位置的大气温度和水蒸气密度分布和压力测量中实施处理中的系数，以提供校正的目标温度数据，以补偿所述原始 数据由于所说的干预气氛。 该方法特别适用于从较便宜但也不太精确的宽带红外测温仪校正数据。

公开(公告)号：US07043369B2

公开(公告)日：2006-05-09

申请号：US10819621

申请日：2004-04-07

Applicant: Marc A. Kolodner ,  Patricia K. Murphy ,  Edward E. Hume

Inventor： Marc A. Kolodner ,  Patricia K. Murphy ,  Edward E. Hume

IPC: G06Q99/00

CPC classification number: G06K9/3241 ,  G01J3/28 ,  G01J3/2823 ,  G01J5/007 ,  G01J2003/2826 ,  G01J2005/0055

Abstract: A method and structure that inputs atmospheric forecast information from the atmospheric forecast database based on current, real time atmospheric measurements. The hyperspectral detection processing unit also inputs at least one selected reflectance library from the reflectance library database, and data collection and sensor parameters from the sensor. With this information, the hyperspectral detection processing unit employs a model to produce at least one mission radiance library during the mission planning phase. Then, during the actual mission execution, the sensor is used to collect the hyperspectral data and the comparator can immediately compare the hyperspectral data to the mission radiance library to identify features and/or targets.

Abstract translation: 一种基于当前实时大气测量从大气预报数据库输入大气预报信息的方法和结构。 高光谱检测处理单元还从反射谱库数据库输入至少一个选定的反射谱库，以及来自传感器的数据收集和传感器参数。 利用这些信息，高光谱检测处理单元在任务规划阶段使用一个模型来生成至少一个任务辐射库。 然后，在实际任务执行期间，传感器用于收集高光谱数据，比较器可以立即将高光谱数据与任务辐射库进行比较，以识别特征和/或目标。

公开(公告)号：US20190219450A1

公开(公告)日：2019-07-18

申请号：US16364559

申请日：2019-03-26

Applicant: Tim Patrick Dubbs ,  John Leonard Shaver ,  Kreg James Kelley ,  Troy M Raybold ,  Tushar Vispute

Inventor： Tim Patrick Dubbs ,  John Leonard Shaver ,  Kreg James Kelley ,  Troy M Raybold ,  Tushar Vispute

IPC: G01J5/50 ,  H04N5/247 ,  G01J5/00 ,  G01J5/08 ,  H04N5/33 ,  G06K9/20 ,  G06K9/32 ,  G06K9/46

CPC classification number: G01J5/505 ,  G01J5/0044 ,  G01J5/089 ,  G01J2005/0048 ,  G01J2005/0051 ,  G01J2005/0055 ,  G01J2005/0077 ,  G06K9/2081 ,  G06K9/3233 ,  G06K9/4661 ,  H04N5/247 ,  H04N5/33

Abstract: A method for measuring furnace temperatures. The method includes obtaining radiance measurements from a plurality of regions of interest (ROIs) using a plurality of thermal imaging cameras, and measuring a surface temperature using a radiance measurement obtained from an ROI selected from the plurality of ROIs. Measuring the surface temperature includes determining an effective background radiance affecting the selected ROI using radiance measurements obtained from ROIs different from the selected ROI, obtaining a compensated radiance by removing the effective background radiance from the radiance measurement obtained from the selected ROI, and converting the compensated radiance to the measured surface temperature.

公开(公告)号：US20180077754A1

公开(公告)日：2018-03-15

申请号：US15703316

申请日：2017-09-13

Applicant: SCREEN HOLDINGS CO., LTD.

Inventor： Yoshio ITO

IPC: H05B3/00 ,  H01L21/67 ,  H05B1/02 ,  G01J5/00 ,  G01J5/04

CPC classification number: H05B3/0047 ,  G01J5/0007 ,  G01J5/041 ,  G01J5/0865 ,  G01J5/602 ,  G01J2005/0055 ,  G01J2005/604 ,  H01L21/67115 ,  H01L21/67248 ,  H01L21/68707 ,  H05B1/0233 ,  H05B3/009

Abstract: An atmosphere of ammonia that absorbs infrared light in a wavelength band overlapping with the measurement wavelength band of a radiation thermometer is formed in a chamber in which a semiconductor wafer is thermally treated. A filter that selectively transmits infrared light having a wavelength not overlapping with the absorption wavelength band of ammonia is installed between an optical lens system and a detector of the radiation thermometer to avoid influence of the infrared light absorption by ammonia. A conversion table corresponding to the installed filter is selected from a plurality of conversion tables representing a correlation between energy of infrared light incident on the radiation thermometer and temperature of a black body, and is used at the radiation thermometer. Accordingly, the temperature of the semiconductor wafer can be accurately measured in the atmosphere of ammonia.

公开(公告)号：US20170160141A1

公开(公告)日：2017-06-08

申请号：US15309517

申请日：2015-05-20

Applicant: Panasonic Corporation

Inventor： HIROSHI YAMANAKA

IPC: G01J5/56 ,  H04N5/33 ,  G01J5/10 ,  G01K1/20 ,  G01J5/52

CPC classification number: G01J5/56 ,  G01J5/0003 ,  G01J5/045 ,  G01J5/06 ,  G01J5/0806 ,  G01J5/0846 ,  G01J5/10 ,  G01J5/12 ,  G01J5/20 ,  G01J5/48 ,  G01J5/52 ,  G01J2005/0048 ,  G01J2005/0055 ,  G01J2005/066 ,  G01J2005/067 ,  G01J2005/106 ,  G01J2005/528 ,  G01K1/20 ,  H04N5/2253 ,  H04N5/2254 ,  H04N5/33

Abstract: A temperature sensor includes a first infrared measuring means, a second infrared measuring means, and a calculating unit. The first infrared measuring means measures infrared rays emitted from an object and outputs a first voltage. The second infrared measuring means measures infrared rays emitted from around the object and outputs a second voltage. The calculating unit calculates the output temperature of the object from the first voltage, calculates the ambient temperature of the object from the second voltage, and corrects the output temperature based on the ambient temperature to calculate the temperature of the object.