Abstract
Constructing a high-precision and high-resolution gravimetric geoid model in the mountainous area is a quite challenging task because of the lack of terrestrial gravity observations, rough topography and the geological complexity. One way out is to use high-quality and well-distributed satellite and airborne gravity data to fill the gravity data gaps; thus, the proper combination of heterogeneous gravity datasets is critical. In a rough topographic area in Colorado, we computed a set of gravimetric geoid models based on different combination modes of satellite gravity models, terrestrial and airborne gravity data using the spectral combination method. The gravimetric geoid model obtained from the combination of satellite gravity model GOCO06S and terrestrial gravity data agrees with the GPS leveling measured geoid heights at 194 benchmarks in 5.8 cm in terms of the standard deviation of discrepancies, and the standard deviation reduces to 5.3 cm after including the GRAV-D airborne gravity data collected at ~ 6.2 km altitude into the data combination. The contributions of airborne gravity data to the signal and accuracy improvements of the geoid models were quantified for different spatial distribution and density of terrestrial gravity data. The results demonstrate that, although the airborne gravity survey was flown at a high altitude, the additions of airborne gravity data improved the accuracies of geoid models by 13.4%–19.8% in the mountainous area (elevations > 2000 m) and 12.7%–21% (elevations < 2000 m) in the moderate area in the cases of terrestrial gravity data spacings are larger than 15 km.
Highlights
In 2017, The Joint Working Group (JWG) 0.1.2 (Strategy for the Realization of the International Height Reference System (IHRS)) and JWG 2.2.2 of the International Association of Geodesy (IAG) jointly launched the Colorado geoid experiment
The results demonstrate that: (1) airborne gravity data can only slightly improve the accuracy of geoid model if the used terrestrial gravity data are densely distributed with the spacing less than or equal to 15 km; (2) airborne gravity data are capable of effectively filling the data gaps of terrestrial gravity and obviously improving the geoid model accuracy when combined with sparsely distributed terrestrial data with the spacing larger than 15 km
A series of gravimetric geoid models in the varied topography area of Colorado were derived based on the different data combination modes of satellite gravity model, terrestrial and GRAV-D airborne gravity data using the spectral combination method, and validated against the historic Global positioning system (GPS) leveling measured geoid heights at 194 benchmarks provided by the National Geodetic Survey (NGS)
Summary
In 2017, The Joint Working Group (JWG) 0.1.2 (Strategy for the Realization of the International Height Reference System (IHRS)) and JWG 2.2.2 (the 1 cm geoid experiment) of the International Association of Geodesy (IAG) jointly launched the Colorado geoid experiment. Several gravimetric geoid models in Colorado were computed from different combination modes of satellite gravity models, terrestrial and airborne gravity data.
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