Critical Points and Technical Approach in the E-OSPF Time Synchronization and Prediction Activities

Abstract

Accurate satellite clock predictions are essential for navigation satellite systems. The user positioning and integrity performances are dependent on the accuracy achieved when the clock estimation and prediction techniques are applied to the generation of the navigation information. This article presents the latest timing approaches prototyped in the E-OSPF (Experimental Orbitography and Synchronization Processing Facility), and the obtained results, related to clock estimation technique, clock prediction fitting strategy, and specific solutions designed for Galileo system clock features. Regarding the clock estimation technique, the OD&TS (Orbit Determination and Time Synchronization) E-OSPF SW module implements an algorithm that allows the existence of a backup time reference to be used in case of lack of observability from the master PTF (Precise Timing Facility). This is particularly useful in the IOV (In-Orbit Validation) configurations, which will allow the verification of the proper functioning of the overall system before entering the FOC (Full Operation Capability) phase. The clock prediction fitting strategy currently implemented in the E-OSPF SW consists of estimating the zero-order clock prediction parameter with a reduced set of clock offsets containing the final epochs in the estimation arc, whereas the first-order clock prediction parameter is computed by fitting the clock offsets in a larger time period, typically as long as the estimation period. This strategy has been demonstrated to be successful with GPS data, and is now being tested for real and simulated Galileo data as well. The fulfillment of the stringent requirements defined for the Galileo system functionality and performances imply that planned and unplanned clock events such as clock switches and resynchronizations, or clock phase jumps, among others, have to be managed by the E-OSPF in such a way the system accuracy, integrity, and availability are preserved.

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Document Details

Document Type
Technical Report
Publication Date
Nov 01, 2007
Accession Number
ADA485512

Entities

People

  • Maria D. Lainez Samper
  • Miguel M. Romay Merino
  • Pedro F. Navarro Madrid

Tags

DTIC Thesaurus Topics

  • Accuracy
  • Algorithms
  • Artificial Satellites
  • Availability
  • Clocks
  • Frequency Standards
  • Global Navigation Satellite Systems
  • Measurement
  • Navigation
  • Navigation Satellites
  • Phase Measurement
  • Range Finding
  • Satellite Orbits
  • Solar Radiation
  • Standards
  • Time Intervals
  • Validation

Readers

  • Computational Modeling and Simulation
  • Positioning, Navigation, and Timing (PNT) Technology.

Technology Areas

  • Space