Journal ArticleDOI
A comparison and analysis of airborne gravimetry results from two strapdown inertial/DGPS systems
Craig Glennie,K. P. Schwarz +1 more
TLDR
In this paper, a 3-day period in the Canadian Rocky Mountains over a single 100 × 100 km area which was flown with 10-km line spacing was used to investigate the long-term accuracy and repeatability of the system, as well as its potential for geoid and vertical gradient of gravity determination.Abstract:
In September 1996 the University of Calgary tested a combination of strapdown inertial navigation systems and differential global positioning system (DGPS) receivers for their suitability to determine gravity at aircraft flying altitudes. The purpose of this test was to investigate the long-term accuracy and repeatability of the system, as well as its potential for geoid and vertical gradient of gravity determination. The test took place during a 3-day period in the Canadian Rocky Mountains over a single 100 × 100 km area which was flown with 10-km line spacing. Two flights were done at 4350 m in E–W and N–S profile directions, respectively, and one at 7300 m with E–W profiles. Two strapdown inertial systems, the Honeywell LASEREF III and the Litton-101 Flagship, were flown side by side. Comparison of the system estimates with an upward-continued reference showed root-mean-square (RMS) agreement at the level of 3.5 mGal for 90- and 120-s filter lengths. The LASEREF III, however, performed significantly better than the Litton 101 for shorter filtering periods of 30 and 60 s. A comparison between the two systems results in an RMS agreement of 2.8 and 2.3 mGal for the 90- and 120-s filters. The better agreement between the two systems is mainly due to the fact that the upward-continued reference has not been filtered identically to the system gravity disturbance estimates. Additional low-frequency differences seem to point to an error in the upward-continued reference. Finally, an analysis of crossover points between flight days for the LASEREF III shows a standard deviation of 1.6 mGal, which is near the noise level of the INS and GPS data. Further improvements to the system are possible, and some ideas for future work are briefly presented.read more
Citations
More filters
DissertationDOI
Improving the accuracy and resolution of SINS/DGPS airborne gravimetry
Abstract: ............................................................................................................................iii Acknowledgements........................................................................................................... iv Dedication .........................................................................................................................vi Table of
Journal ArticleDOI
Differentiation for High-Precision GPS Velocity and Acceleration Determination
TL;DR: In this article, a comprehensive study of possible differentiation methods, characterizing each in the frequency domain and using real data to demonstrate each of these methods in both of the measurement and position domains, in conditions of variable, high, or unknown dynamics.
Book ChapterDOI
Airborne Gravity Field Determination
TL;DR: Agarwal et al. as mentioned in this paper used a carrier-phase kinematic GPS method to estimate the position of gravity anomalies for geodesy and geophysics, and achieved an accuracy of 1 mGal (10−5 m/s2) or less at a resolution of a few kilometers for several commercial operators.
Journal ArticleDOI
A comparison of stable platform and strapdown airborne gravity
TL;DR: In this article, three flight tests were undertaken which tested a LCR gravimeter and the Honeywell Laseref III (LRF III) strapdown inertial navigation system side-by-side in the same airplane.
Airborne Scalar Gravimetry for Regional Gravity Field Mapping and Geoid Determination
TL;DR: In this article, a new algorithm to correct for platform off-leveling errors is derived and it is shown that this new algorithm in combination with the good drift characteristic for the spring type gravimeter yields virtual bias free data.
References
More filters
Book
Control of spacecraft and aircraft
TL;DR: In this paper, the linear-quadratic-regulator (LQR) method of feedback control synthesis is used to coordinate multiple controls, producing graceful maneuvers comparable to those of an expert pilot.
Journal ArticleDOI
Flight test results from a strapdown airborne gravity system
M. Wei,K. P. Schwarz +1 more
TL;DR: In this article, a flight test was carried out over the Rocky Mountains to assess the accuracy of airborne gravity for geoid determination, which was the first time that a strapdown inertial navigation system (INS) has been used for airborne gravimetry.
Journal ArticleDOI
A Strapdown Inertial Algorithm Using an Earth-Fixed Cartesian Frame
M. Wei,K. P. Schwarz +1 more
TL;DR: In this article, an algorithm for processing inertial data in an earth-fixed Cartesian frame is developed, which is compared with the standard algorithm that uses the local-level frame and the geographic coordinate system for the model formulation.
Book ChapterDOI
An introduction to airborne gravimetry and its boundary value problems
K. P. Schwarz,Zuofa Li +1 more
TL;DR: In this article, three major aspects of airborne gravimetry are presented: Introduction to system concepts, modelling of observables and estimation, boundary value problems, and boundary value problem analysis.