Patents by Inventor William I. Bertiger

William I. Bertiger has filed for patents to protect the following inventions. This listing includes patent applications that are pending as well as patents that have already been granted by the United States Patent and Trademark Office (USPTO).

  • Patent number: 9261597
    Abstract: Novel methods and systems for the accurate and efficient processing of real-time and latent global navigation satellite systems (GNSS) data are described. Such methods and systems can perform orbit determination of GNSS satellites, orbit determination of satellites carrying GNSS receivers, positioning of GNSS receivers, and environmental monitoring with GNSS data.
    Type: Grant
    Filed: May 8, 2015
    Date of Patent: February 16, 2016
    Assignee: CALIFORNIA INSTITUTE OF TECHNOLOGY
    Inventors: Yoaz E. Bar-Sever, William I. Bertiger, Angela R. Dorsey, Nathaniel E. Harvey, Wenwen Lu, Kevin J. Miller, Mark A. Miller, Larry J. Romans, Anthony J. Sibthorpe, Jan P. Weiss, Miquel Garcia Fernandez, Jason Gross
  • Publication number: 20150234052
    Abstract: Novel methods and systems for the accurate and efficient processing of real-time and latent global navigation satellite systems (GNSS) data are described. Such methods and systems can perform orbit determination of GNSS satellites, orbit determination of satellites carrying GNSS receivers, positioning of GNSS receivers, and environmental monitoring with GNSS data.
    Type: Application
    Filed: May 8, 2015
    Publication date: August 20, 2015
    Inventors: Yoaz E. BAR-SEVER, William I. BERTIGER, Angela R. DORSEY, Nathaniel E. HARVEY, Wenwen LU, Kevin J. MILLER, Mark A. MILLER, Larry J. ROMANS, Anthony J. SIBTHORPE, Jan P. WEISS, Miquel Garcia FERNANDEZ, Jason GROSS
  • Patent number: 9057780
    Abstract: Novel methods and systems for the accurate and efficient processing of real-time and latent global navigation satellite systems (GNSS) data are described. Such methods and systems can perform orbit determination of GNSS satellites, orbit determination of satellites carrying GNSS receivers, positioning of GNSS receivers, and environmental monitoring with GNSS data.
    Type: Grant
    Filed: April 18, 2014
    Date of Patent: June 16, 2015
    Assignee: CALIFORNIA INSTITUTE OF TECHNOLOGY
    Inventors: Yoaz E. Bar-Sever, William I. Bertiger, Angela R. Dorsey, Nathaniel E. Harvey, Wenwen Lu, Kevin J. Miller, Mark A. Miller, Larry J. Romans, Anthony J. Sibthorpe, Jan P. Weiss, Miquel Garcia Fernandez, Jason Gross
  • Publication number: 20140316697
    Abstract: Novel methods and systems for the accurate and efficient processing of real-time and latent global navigation satellite systems (GNSS) data are described. Such methods and systems can perform orbit determination of GNSS satellites, orbit determination of satellites carrying GNSS receivers, positioning of GNSS receivers, and environmental monitoring with GNSS data.
    Type: Application
    Filed: April 18, 2014
    Publication date: October 23, 2014
    Applicant: CALIFORNIA INSTITUTE OF TECHNOLOGY
    Inventors: Yoaz E. BAR-SEVER, William I. BERTIGER, Angela R. DORSEY, Nathaniel E. HARVEY, Wenwen LU, Kevin J. MILLER, Mark A. MILLER, Larry J. ROMANS, Anthony J. SIBTHORPE, Jan P. WEISS, Miquel Garcia FERNANDEZ, Jason GROSS
  • Patent number: 8120529
    Abstract: Methods and apparatus for autonomous in-receiver prediction of orbit and clock states of Global Navigation Satellite Systems (GNSS) are described. Only the GNSS broadcast message is used, without need for periodic externally-communicated information. Earth orientation information is extracted from the GNSS broadcast ephemeris. With the accurate estimation of the Earth orientation parameters it is possible to propagate the best-fit GNSS orbits forward in time in an inertial reference frame. Using the estimated Earth orientation parameters, the predicted orbits are then transformed into Earth-Centered-Earth-Fixed (ECEF) coordinates to be used to assist the GNSS receiver in the acquision of the signals. GNSS satellite clock states are also extracted from the broadcast ephemeris and a parameterized model of clock behavior is fit to that data. The estimated modeled clocks are then propagated forward in time to enable, together with the predicted orbits, quicker GNSS signal acquision.
    Type: Grant
    Filed: September 11, 2008
    Date of Patent: February 21, 2012
    Assignee: California Institute of Technology
    Inventors: Yoaz E. Bar-Sever, William I. Bertiger
  • Publication number: 20100060518
    Abstract: Methods and apparatus for autonomous in-receiver prediction of orbit and clock states of Global Navigation Satellite Systems (GNSS) are described. Only the GNSS broadcast message is used, without need for periodic externally-communicated information. Earth orientation information is extracted from the GNSS broadcast ephemeris. With the accurate estimation of the Earth orientation parameters it is possible to propagate the best-fit GNSS orbits forward in time in an inertial reference frame. Using the estimated Earth orientation parameters, the predicted orbits are then transformed into Earth-Centered-Earth-Fixed (ECEF) coordinates to be used to assist the GNSS receiver in the acquision of the signals. GNSS satellite clock states are also extracted from the broadcast ephemeris and a parametrized model of clock behavior is fit to that data. The estimated modeled clocks are then propagated forward in time to enable, together with the predicted orbits, quicker GNSS signal acquision.
    Type: Application
    Filed: September 11, 2008
    Publication date: March 11, 2010
    Inventors: Yoaz E. Bar-Sever, William I. Bertiger
  • Patent number: 6295021
    Abstract: Techniques for monitoring and controlling yawing of a GPS satellite in an orbit that has an eclipsing portion out of the sunlight based on the orbital conditions of the GPS satellite. In one embodiment, a constant yaw bias is generated in the attitude control system of the GPS satellite to control the yawing of the GPS satellite when it is in the shadow of the earth.
    Type: Grant
    Filed: August 18, 1999
    Date of Patent: September 25, 2001
    Assignee: California Institute of Technology
    Inventors: Stephen M. Lichten, Yoaz Bar-Sever, James Zumberge, William I. Bertiger, Ronald J. Muellerschoen, Sien-Chong Wu, Kenneth Hurst, Geoff Blewitt, Thomas Yunck, Catherine Thornton, Michael Heflin
  • Patent number: 5963167
    Abstract: An improved analyzing system based on GIPSY-OASIS II software package developed at the Jet Propulsion Laboratory for Global Positioning System, general satellite tracking, orbit determination and trajectory studies. New features and functions include yaw compensation, precise satellite positioning by high-rate GPS clocks, enhanced data filtering and smoothing, a new user interface for controlling orientation of a satellite and its components, and no-fiducial approach to global geodesy. The present invention allows a fully automatic operation and delivery of validated daily solutions for orbits, clocks, station locations and others with no human intervention. A 3D GPS orbit accuracy of 15 cm and the daily repeatability of the 3D global geocentric station location in better than 1 cm have been achieved.
    Type: Grant
    Filed: March 13, 1997
    Date of Patent: October 5, 1999
    Assignee: California Institute of Technology
    Inventors: Stephen M. Lichten, Sien-Chong Wu, Kenneth Hurst, Geoff Blewitt, Thomas Yunck, Yoaz Bar-Sever, James Zumberge, William I. Bertiger, Ronald J. Muellerschoen, Catherine Thornton, Michael Heflin
  • Patent number: 5828336
    Abstract: The present invention provides a method and a device for providing superior differential GPS positioning data. The system includes a group of GPS receiving ground stations covering a wide area of the Earth's surface. Unlike other differential GPS systems wherein the known position of each ground station is used to geometrically compute an ephemeris for each GPS satellite, the present system utilizes real-time computation of satellite orbits based on GPS data received from fixed ground stations through a Kalman-type filter/smoother whose output adjusts a real-time orbital model. The orbital model produces and outputs orbital corrections allowing satellite ephemerides to be known with considerable greater accuracy than from the GPS system broadcasts. The modeled orbits are propagated ahead in time and differenced with actual pseudorange data to compute clock offsets at rapid intervals to compensate for SA clock dither.
    Type: Grant
    Filed: March 29, 1996
    Date of Patent: October 27, 1998
    Assignee: The United States of America as represented by the Administrator of the National Aeronautics and Space Administration
    Inventors: Thomas P. Yunck, William I. Bertiger, Stephen M. Lichten, Anthony J. Mannucci, Ronald J. Muellerschoen, Sien-Chong Wu