Monitoring station location determination for a satellite navigation system

US 6,138,074 A
Filed: 12/23/1998
Issued: 10/24/2000
Est. Priority Date: 12/23/1998
Status: Expired due to Term

First Claim

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1. In a global positioning system including satellites which transmit navigation signals from which a user can determine his position and including a differential correction system in which the range between at least three receiving stations in fixed positions and said satellites are measured from said navigation signals and are compared to the actual ranges between said satellites and said receiving stations to compute differential correction information including corrections to satellite clock times and corrections to the satellite positions;

a method of determining the positions of said receiving stations comprising establishing a database of receiving station site positions for use in said differential correction system, removing a first one said receiving stations from said differential correction system and calculating said differential correction information from the site positions in said database over a selected time interval while the site position of said first receiving station is removed from the calculations of said differential correction information, determining the position of said first one of said receiving stations from said navigation signals and said differential correction information and updating the site position of said first one of said receiving stations in said database with the site position of said first one of said receiving stations determined from said navigation signals and said differential correction information, then removing a second one of said receiving stations from said differential correction system and calculating said differential correction information over a selected time interval from site positions in said database including the updated site position of said first one of said receiving stations while the site position of said second one of said receiving stations is removed from the calculations of said differential correction information, determining the site position of said second one of said receiving stations from said navigation signals and said differential correction information and updating the site position of said second one of said receiving stations in said database with the site position of said second one of said receiving stations determined from said navigation signals and said differential correction information, removing a third one of said receiving stations from said differential correction system and calculating said differential correction information over a selected time interval from site positions in said data base including the updated site position of said first one of said receiving stations and the updated site position of said second one of said receiving stations while the site position of said third one of said receiving stations is removed from the calculations of said differential correction information, determining the site position of said third one of said receiving stations from said navigational signals and said differential correction information and updating the site position of said third one of said receiving stations in said data base with the site position of said third one of said receiving stations determined from said navigation signals and said differential correction information.

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Abstract

In a global positioning system, satellites transmit navigation signals to users which determine their position from the received navigation signals. A wide area differential correction system employs receiving stations in fixed positions on the ground and compares ranges between the receiving stations and the satellites measured from the navigation signals with the actual ranges between the satellites and the receiving stations to determine correction information including corrections in the satellite clock times and the satellite positions to be transmitted to the users and from which the users can more accurately determine their positions. The site locations of the receiving stations to be used in the wide area differential correction system are determined by first determining an initial estimate of the site locations by means of a global positioning system and storing these initial estimates in a data base and then removing each receiving station from the wide area differential correction system in turn and calculating the wide area differential corrections without use of the site location of the removed receiving station. The site location of the removed station is then determined using the global positioning system and the wide area differential calculations and the site location of the removed station is updated in the data base with the site location thus determined. This process is repeated for each receiving station in turn three times to determine an accurate updated data base of site locations for the receiving stations to be used in the wide area differential correction system.

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14 Claims

1. In a global positioning system including satellites which transmit navigation signals from which a user can determine his position and including a differential correction system in which the range between at least three receiving stations in fixed positions and said satellites are measured from said navigation signals and are compared to the actual ranges between said satellites and said receiving stations to compute differential correction information including corrections to satellite clock times and corrections to the satellite positions;
- a method of determining the positions of said receiving stations comprising establishing a database of receiving station site positions for use in said differential correction system, removing a first one said receiving stations from said differential correction system and calculating said differential correction information from the site positions in said database over a selected time interval while the site position of said first receiving station is removed from the calculations of said differential correction information, determining the position of said first one of said receiving stations from said navigation signals and said differential correction information and updating the site position of said first one of said receiving stations in said database with the site position of said first one of said receiving stations determined from said navigation signals and said differential correction information, then removing a second one of said receiving stations from said differential correction system and calculating said differential correction information over a selected time interval from site positions in said database including the updated site position of said first one of said receiving stations while the site position of said second one of said receiving stations is removed from the calculations of said differential correction information, determining the site position of said second one of said receiving stations from said navigation signals and said differential correction information and updating the site position of said second one of said receiving stations in said database with the site position of said second one of said receiving stations determined from said navigation signals and said differential correction information, removing a third one of said receiving stations from said differential correction system and calculating said differential correction information over a selected time interval from site positions in said data base including the updated site position of said first one of said receiving stations and the updated site position of said second one of said receiving stations while the site position of said third one of said receiving stations is removed from the calculations of said differential correction information, determining the site position of said third one of said receiving stations from said navigational signals and said differential correction information and updating the site position of said third one of said receiving stations in said data base with the site position of said third one of said receiving stations determined from said navigation signals and said differential correction information.
- View Dependent Claims (2, 3, 4, 5, 6, 7)
- - 2. A method as recited in claim 1, wherein said data base of receiving stations site positions is initially determined from said navigation signals.
  - 3. A method as recited in claim 1, wherein said site positions of said receiving stations are initially unknown and said database of site positions is initially determined from the navigation signals without use of differential corrections computed by said differential correction system.
  - 4. A method as recited in claim 1, wherein the site positions of a plurality of said receiving stations are unknown and one or more of said plurality of receiving stations is a transportable receiving station.
  - 5. A method as recited in claim 1, further comprising calculating said differential corrections from said data base of receiving stations site positions after all of their receiving site positions of receiving stations which were unknown have been updated and transmitting the differential correction information computed from the updated database to a user receiving navigation signals from said satellites, said last named user using said navigation signals and the transmitted differential correction information to determine said last named user'"'"'s position.
  - 6. A method as recited in claim 1, wherein said differential correction system is a wide area differential correction system.
  - 7. A method as recited in claim 6, wherein the differential correction information calculated by said wide area differential correction system is included in a correction message transmitted to user and wherein said correction message includes information for troposphere and ionosphere distortion correction.

8. In a global positioning system including satellites which transmit navigation signals from which a user can determine his position and including a differential correction system in which the range between the receiving stations in fixed positions and said satellites are measured from said navigation signals and are compared to the actual ranges between said satellites and said receiving stations to compute the differential correction information including corrections to satellite clock times and corrections to satellite positions;
- a method of determining the positions of said receiving stations comprising establishing a database of receiving stations site positions for use in said differential correction system and then updating the site position of each receiving station in said database in turn in accordance with the following steps;
  
  1) removing the selected receiving station from said differential correction system and calculating said differential correction information from the site positions as currently updated in said data base over a selected time interval while the site position of the selected receiving station is removed from the calculations of said differential correction information,2) determining the position of the selected receiving station from said navigation signals and said differential correction information,3) replacing the site position of the selected receiving station in said data base with the site position determined in step 2, and4) repeating steps 1-3 on each receiving station a second time.
- View Dependent Claims (9, 10, 11, 12, 13, 14)
- - 9. In a method as recited in claim 8, further comprising calculating said differential correction information from the updated data base after performing said steps 1-3 on each of said receiving stations at least twice and transmitting the differential correction information to a user wherein said last named user uses said navigation signals and said differential correction information to determine the user'"'"'s position.
  - 10. A method as recited in claim 8, wherein said database of receiving station site positions is initially determined from said navigation signals.
  - 11. A method as recited in claim 8, wherein the site positions of said receiving stations are initially unknown and wherein the site positions in said database is initially determined from said navigation signals without use of differential corrections computed by said differential correction system.
  - 12. A method as recited in claim 8, wherein the site positions of a plurality of said receiving stations are unknown and one or more of said plurality is a transportable receiving station.
  - 13. A method as recited in claim 8, wherein said differential correction system is a wide area differential correction system.
  - 14. A method as recited in claim 13, wherein the correction calculated by said wide area differential correction system is included in a correction message transmitted to user and wherein said correction message includes information for troposphere and ionosphere distortion correction.

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Litigation Campaign Assessment

Current Assignee
Lockheed Martin Corporation (Martin Marietta Corporation)
Original Assignee
Lockheed Martin Corporation (Martin Marietta Corporation)
Inventors
Gower, Arthur G., Rudd, Jack George, Beisner, Henry M.
Primary Examiner(s)
Cuchlinski, Jr., William A.
Assistant Examiner(s)
Beaulieu, Yonel

Application Number

US09/220,689
Time in Patent Office

671 Days
Field of Search

701/215, 701/206, 701/207, 701/213, 701/214, 342/357.01, 342/357.03, 342/357.06, 342/450, 342/457, 342/463, 455/39, 455/40, 455/500, 370/310, 370/312, 370/328
US Class Current

701/215
CPC Class Codes

G01S 19/071 DGPS corrections

Monitoring station location determination for a satellite navigation system

First Claim

1 Assignment

0 Petitions

Accused Products

Abstract

31 Citations

14 Claims

Specification

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Monitoring station location determination for a satellite navigation system

First Claim

1 Assignment

Subscription Required

Subscription Required

0 Petitions

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Accused Products

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Abstract

31 Citations

14 Claims

Specification

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Use Cases

Quick Links

Others