Patents Assigned to University Corporation for Atmospheric Research
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Patent number: 7583364Abstract: An eye-safe atmospheric aerosol lidar featuring high transmit pulse energy to generate strong backscatter from long ranges in a single pulse together with an optically efficient receiver is disclosed. The transmitter employs a gas cell and non-focused laser beam geometry to convert short wavelength laser light to substantially safer and longer wavelength light by stimulated Raman scattering. The longer wavelength light is substantially safer than the shorter wavelength light thereby allowing the safe transmission of high energy pulses. The transmitter also features a diode injection seed and a beam expander which are effective to reduce the divergence of the long wavelength light below the field-of-view of the receiver. The receiver employs a telescope, collimating lens, interference filter, focusing lens, avalanche photodiode detector, amplifier and analog to digital converter. The transmit beam and receiver field of view are coaxial.Type: GrantFiled: March 19, 2004Date of Patent: September 1, 2009Assignee: University Corporation for Atmospheric ResearchInventors: Shane Mayor, Scott Spuler
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Patent number: 7580127Abstract: A polarization lidar system capable of remotely identifying characteristics of atmospheric aerosol particles by transmitting a polarized beam of light and analyzing polarization characteristics of received backscatter is disclosed. The transmitter features high pulse energy to remotely identify aerosol particles with substantially one pulse. The transmitter employs a thin film plate polarizer and a Raman wavelength shifter to achieve eye-safe, single-plane linearly polarized energy. The transmit beam and receiver field of view are coaxial. The receiver employs a telescope, a collimating lens, and a beam splitter. The beam splitter splits the received backscatter into a single-plane polarized beam whose polarization plane is parallel to the plane of transmission and a single-plane polarized beam whose polarization plane is perpendicular to the plane of transmission. Each split beam is directed through separate focusing lenses onto separate detectors.Type: GrantFiled: July 21, 2006Date of Patent: August 25, 2009Assignee: University Corporation for Atmospheric ResearchInventors: Shane Mayor, Scott Spuler
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Patent number: 7369053Abstract: A de-icing information system processes weather data indicating precipitation rate and temperature to determine a check time for a de-icing fluid. The de-icing fluid remains effective if applied after the check time, and the de-icing fluid may not remain effective if applied before the check time. The de-icing information system transfers the de-icing information indicating the check time.Type: GrantFiled: September 8, 2006Date of Patent: May 6, 2008Assignee: University Corporation for Atmospheric ResearchInventors: Roy Martin Rasmussen, Frank W. Hage, Rondal K. Moore
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Patent number: 7340949Abstract: A precipitation measurement device measures a precipitation rate of falling precipitation. A first probe is exposed to the falling precipitation. A first temperature sensor detects a first probe temperature. A second probe is shielded from the falling precipitation. A second temperature sensor detects a second probe temperature. A heating element heats the first probe and the second probe when turned on, but not when turned off. After being heated and when the heating element is turned off, the first probe cools at a first temperature drop rate, and the second probe cools at a second temperature drop rate. Circuitry processes a difference between the first temperature drop rate and the second temperature drop rate to determine the precipitation rate of the falling precipitation.Type: GrantFiled: November 8, 2006Date of Patent: March 11, 2008Assignee: University Corporation for Atmospheric ResearchInventor: Frank William Hage
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Publication number: 20070292046Abstract: An optical adapter for an imaging system correcting images of spherical or near spherical bodies such as the earth during satellite image collection. An imaging system includes an image collector that collects a two-dimensional image of the body from a distance above the body such as from a satellite in geostationary orbit. The collected image is disk shaped and includes distortion due to earth curvature, primarily in the form of a loss of resolution due to the foreshortening of earth features in a radial direction extending outward from the center of the image disk. The optical adapter receives the collected image, transforms the collected image to correct the distortion, and outputs a corrected image with essentially uniform spatial resolution across the areas for which the correction is applied. An image sensor such as charge-coupled device array senses the corrected image and creates a digital representation of the corrected image.Type: ApplicationFiled: April 27, 2007Publication date: December 20, 2007Applicant: UNIVERSITY CORPORATION FOR ATMOSPHERIC RESEARCHInventor: David Johnson
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Publication number: 20070217009Abstract: A method, element and system are provide for efficiently, accurately and without significant contribution of noise, splitting a beam of radiation or combining beams of radiation. In one embodiment of the invention, a beamsplitter front surface partially reflects incident radiation and refracts the rest of the radiation. The refracted radiation is completely reflected at a back surface of the beamsplitter and is completely refracted producing a parallel beam without creating any stray radiation or optical noise. This is accomplished using a p-polarized input beam and a Brewster angle geometry.Type: ApplicationFiled: March 17, 2006Publication date: September 20, 2007Applicant: University Corporation for Atmospheric ResearchInventor: Dirk Richter
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Patent number: 7191643Abstract: A sensor system comprises a first sensor, a second sensor, and circuitry. The first sensor collects non-frozen liquid with a first collection efficiency, but does not collect frozen liquid. The second sensor collects non-frozen liquid with a second collection efficiency and also collects frozen liquid. The first collection efficiency and the second collection efficiency are substantially equivalent. The circuitry maintains the first sensor and the second sensor at a substantially constant temperature. The circuitry determines a measurement of the frozen liquid based on maintaining the first sensor and the second sensor at the substantially constant temperature. In some examples, multiple sensor systems can be used in combination to improve the accuracy of the measurement.Type: GrantFiled: December 22, 2004Date of Patent: March 20, 2007Assignees: University Corporation for Atmospheric Research, The Board of Regents of the University & Community College Systems of Nevada on behalf of Desert Research InstituteInventors: Roy Martin Rasmussen, John Hallett
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Patent number: 7156552Abstract: A temperature sensor system includes a body and window arrangement. The body defines an air intake and is flush mounted to a mobile platform having a boundary layer. The window arrangement is integrated into the body and transfers a first signal and receives a second signal. The second signal represents energy from the first signal that is reflected by air particles beyond the boundary layer. The second signal is processed to determine a temperature beyond the boundary layer. The air intake receives air particles, transfers a first set of the air particles to a first air vent into the mobile platform, receives the first set of the air particles from a second air vent from the mobile platform, vents the first set of the air particles, and vents a second set of the air particles that bypass the first air vent.Type: GrantFiled: September 7, 2004Date of Patent: January 2, 2007Assignee: University Corporation for Atmospheric ResearchInventor: Rex J. Fleming
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Patent number: 7129846Abstract: A de-icing information system processes weather data indicating precipitation rate and temperature to determine a check time for a de-icing fluid. The de-icing fluid remains effective if applied after the check time, and the de-icing fluid may not remain effective if applied before the check time. The de-icing information system transfers the de-icing information indicating the check time.Type: GrantFiled: August 24, 2004Date of Patent: October 31, 2006Assignee: University Corporation for Atmospheric ResearchInventors: Roy Martin Rasmussen, Frank W. Hage, Rondal K. Moore
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Patent number: 7053813Abstract: A radar system determines the range and velocity of a target, such as an atmospheric structure. The radar system transfers a first series of pulses and a second series of pulses. The first series of pulses and the second series of pulses have orthogonal polarizations. The first series of pulses and the second series of pulses have a same pulse repetition time. The first series of pulses and the second series of pulses are offset by a time amount. The target reflects energy from the first series of pulses to generate a first series of echoes and reflects energy from the second series of pulses to generate a second series of echoes. The radar system processes the first series of echoes and the second series of echoes to determine the range and velocity of the target.Type: GrantFiled: April 22, 2004Date of Patent: May 30, 2006Assignee: University Corporation for Atmospheric ResearchInventors: John Clark Hubbert, Venkatachalam Chandraskaran
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Patent number: 6997050Abstract: A sensor system includes an enclosure mounted externally on an aerial vehicle and a sensor chamber mounted internally within the aerial vehicle. The enclosure receives and converges air particles to cause inertial separation that transfers a first portion of the air particles to a first air transfer path and that causes a second portion of the air particles to bypass the first air transfer path. The first air transfer path transfers the first portion of the air particles from the enclosure to the sensor chamber. The sensor chamber includes at least one sensor that produces sensor data for the first portion of the air particles. A second air transfer path transfers the first portion of the air particles from the sampling chamber to the enclosure. The enclosure transfers the first portion of the air particles and the second portion of the air particles to the atmosphere.Type: GrantFiled: September 9, 2004Date of Patent: February 14, 2006Assignee: University Corporation for Atmospheric ResearchInventor: Rex J. Fleming
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Patent number: 6853331Abstract: A method of compensating for atmospheric effects to detect the actual location of low elevation objects using near horizon radar to detect an object which utilizes a preexisting satellite structured to send a signal indicating the position and velocity of said satellite, wherein the location of the satellite is known. The method includes a step of providing a radar site, a first receiver structured to receive a signal from the satellite indicating an apparent location of the satellite, and a second receiver, located at a distance from the radar site, structured to receive the satellite signal and which indicates the observed location of the satellite. The first receiver is utilized to receive a signal from the satellite when the satellite is at a low elevation. This signal indicates the apparent location and velocity of the satellite.Type: GrantFiled: February 20, 2003Date of Patent: February 8, 2005Assignees: Georgia Tech Research Corporation, University Corporation for Atmospheric ResearchInventors: Mikhail S. Belen'kii, Ernest Jefferson Holder, Susan Ferebee Dugas, Christian Rocken, Anthony Lowry
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Patent number: 6833805Abstract: A method of compensating for atmospheric effects to detect the actual location of low elevation objects using near horizon radar to detect an object which utilizes a preexisting satellite, wherein the location of the satellite is known. The method includes a step of providing a radar site, a first receiver structured to receive a signal from the satellite, and known location data for the satellite then positioning the first receiver near the radar site. The first receiver is utilized to receive a signal from the satellite when the satellite is at a low elevation. The bending angle can then be determined by comparing the apparent location data of the satellite as determined by the first receiver to the known location data of the satellite. This data may also be combined with weather data is used to determine a three dimensional refractivity model. Once the bending angle of the atmosphere is determined, the radar is used to detect the apparent location data of a low elevation object.Type: GrantFiled: February 20, 2003Date of Patent: December 21, 2004Assignees: Georgia Tech Research Corporation, University Corporation for Atmospheric ResearchInventors: Mikhail S. Belen'kii, Ernest Jefferson Holder, Susan Ferebee Dugas
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Patent number: 6813563Abstract: An atmospheric data measurement system comprises an atmospheric sensor, personal digital assistant, link, power system, and enclosure. The atmospheric sensor measures an atmospheric parameter and generates data indicating the atmospheric parameter. The link transfers the data from the atmospheric sensor to the personal digital assistant. The personal digital assistant receives, stores, and transfers the data. The power system provides power to the atmospheric sensor and the personal digital assistant. The enclosure houses the atmospheric sensor, the personal digital assistant, the link, and the power system.Type: GrantFiled: April 8, 2003Date of Patent: November 2, 2004Assignee: University Corporation for Atmospheric ResearchInventors: William E. Bradley, Ryan W-M. Schnell, Pierre-Louis Prevost, James P. Greenberg, Alex B. Guenther
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Patent number: 6809648Abstract: An aerial sampler system includes an enclosure, a transfer system, and a measurement system. The enclosure is connected to an external surface of an aerial vehicle and receives atmospheric flow from the external surface of the aerial vehicle. The enclosure also directs at least some of the atmospheric flow into an aperture in the external surface. The transfer system transfers some of the atmospheric flow from the aperture to a measurement system. The measurement system is internal to the external surface of the aerial vehicle and measures atmospheric trace gases in the atmospheric flow.Type: GrantFiled: November 26, 2002Date of Patent: October 26, 2004Assignee: University Corporation for Atmospheric ResearchInventor: Rex J. Fleming
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Patent number: 6756592Abstract: A system for tomographic sounding using infrared radiation, said system comprising a plurality of gas correlation cameras, each of said cameras comprising at least two gas correlation cells, one of said cells filled with a first gas capable of absorbing infrared radiation at one infrared band and another of said cells filled with a second first gas capable of absorbing infrared radiation at another inked band, and a camera with imaging optics for determining both the spectral and energy content of said first infrared band and the spectral and energy content of said second infrared band.Type: GrantFiled: August 1, 2001Date of Patent: June 29, 2004Assignee: University Corporation for Atmospheric ResearchInventors: Mark William Smith, Boris Vyacheslavovich Khattatov
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Patent number: 6751571Abstract: A precipitation measuring system comprising a top thermal plate positioned to maximize exposure to falling precipitation and includes at least one ridge circumscribing the top surface for capturing precipitation. A second thermal plate is positioned under the top thermal plate to protect it from falling precipitation while still exposing it to the same atmospheric temperature and wind conditions. At least one solar radiation sensor is connected to the precipitation measuring system to measure solar radiation contacting at least one of the top and bottom thermal plates. During a precipitation event, the top and bottom thermal plates are maintained at a constant temperature and a power consumption curve for each thermal plate is quantified. The precipitation rate is measured by the difference in the power consumption curve for the top thermal plate and the power consumption curve for the bottom thermal plate.Type: GrantFiled: February 18, 2003Date of Patent: June 15, 2004Assignees: University Corporation for Atmospheric Research, The Board of Regents of the University & Community College System of Nevada on behalf of Desert Research Inst.Inventors: John Hallett, Roy Martin Rasmussen
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Patent number: 6735550Abstract: A processing system uses image processing technology to classify features in time series data. In atmospheric applications, the features can be used to detect outliers and/or failure modes in time series data from atmospheric measurement systems. The processing system is configured to: 1) process the time series data with a plurality of membership functions to generate a plurality of hypersurfaces, 2) process the hypersurfaces to generate a composite hypersurface, 3) process the composite hypersurface to identify clusters, and 4) process the clusters to classify the features.Type: GrantFiled: January 15, 2002Date of Patent: May 11, 2004Assignee: University Corporation for Atmospheric ResearchInventors: Richard A. Weekley, Robert K. Goodrich, Lawrence B. Cornman
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Patent number: 6731906Abstract: The present system for determining the phase and amplitude of a radio occultation signal modifies the traditional Open Loop tracking process to maximize the signal-to-noise ratio, minimize the sampling rate, and also preserve the structure of the radio occultation signals. A radio occultation system includes a transmitter system, a receiver system, and a post-processing system. The receiver system receives the radio signal that is transmitted by the transmitter system through the earth's atmosphere, where it is occulted, and down converts the received radio occultation signal to generate a down converted signal based on a phase model that uses a refractivity climatology. The receiver system then low pass filters the down converted signal and samples the in-phase and quadrature components of the down converted and low pass filtered signal.Type: GrantFiled: April 23, 2001Date of Patent: May 4, 2004Assignee: University Corporation for Atmospheric ResearchInventors: Sergey V. Sokolovskiy, Christian Rocken
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Patent number: 6714869Abstract: A precipitation measuring system comprising a top thermal plate positioned to maximize exposure to falling precipitation and includes at least one ridge circumscribing the top surface for capturing precipitation. A second thermal plate is positioned under the top thermal plate to protect it from falling precipitation while still exposing it to the same atmospheric temperature and wind conditions. At least one solar radiation sensor is connected to the precipitation measuring system to measure solar radiation contacting at least one of the top and bottom thermal plates. During a precipitation event, the top and bottom thermal plates are maintained at a constant temperature and a power consumption curve for each thermal plate is quantified. The precipitation rate is measured by the difference in the power consumption curve for the top thermal plate and the power consumption curve for the bottom thermal plate.Type: GrantFiled: February 18, 2003Date of Patent: March 30, 2004Assignees: University Corporation for Atmospheric Research, The Board of Regents of the University of College System of NevadaInventors: John Hallett, Roy Martin Rasmussen