Validation of calibrated GOCE gravity gradients GRD_SPW_2 by least-squares spectral weighting
- 1NTIS - New Technologies for the Information Society, Department of Geomatics, Plzeň, Czechia
- 2Faculty of Science and Technology (RealTek), Norwegian University of Life Sciences (NMBU), P.O. Box 5003, NO-1432 Ås, Norway
- 3Norwegian Mapping Authority, Kartverksveien 21, 3507 Hønefoss, Norway
The Gravity field and steady-state Ocean Circulation Explorer (GOCE) was the first mission which carried a novel instrument, gradiometer, which allowed to measure the second-order directional derivatives of the gravitational potential or gravitational gradients with uniform quality and a near-global coverage. More than three years of the outstanding measurements resulted in two levels of data products (Level 1b and Level 2), six releases of global gravitational models (GGMs), and several grids of gravitational gradients (see, e.g., ESA-funded GOCE+ GeoExplore project or Space-wise GOCE products). The grids of gravitational gradients represent a step between gravitational gradients measured directly along the GOCE orbit and data directly from GGMs. One could use grids of gravitational gradients for geodetic as well as for geophysical applications. In this contribution, we are going to validate the official Level 2 product GRD_SPW_2 by terrestrial gravity disturbances and GNSS/levelling over two test areas located in Europe, namely in Norway and former Czechoslovakia (now Czechia and Slovakia). GRD_SPW_2 product contains all six gravity gradients at satellite altitude from the space-wise approach computed only from GOCE data for the available time span (r-2, r-4, and r-5) and provided on a 0.2 degree grid. A mathematical model based on a least-squares spectral weighting will be developed and the corresponding spectral weights will be presented for the validation of gravitational gradients grids. This model allows us to continue downward gravitational gradients grids to an irregular topographic surface (not to a mean sphere) and transform them into gravity disturbances and/or geoidal heights in one step. Before we compared results obtained by spectral downward continuation, we had to remove the high-frequency part of the gravitational signal from terrestrial data because in gravitational gradients measured at GOCE satellite altitude is attenuated. To do so we employ EGM2008 up to d/o 2160 and the residual terrain model correction (RTC) has been a) interpolated from ERTM2160 gravity model, b) synthesised from dV_ELL_Earth2014_5480_plusGRS80, c) calculated from a residual topographic model by forward modelling in the space domain.
How to cite: Pitoňák, M., Šprlák, M., Ophaug, V., Omang, O., and Novák, P.: Validation of calibrated GOCE gravity gradients GRD_SPW_2 by least-squares spectral weighting , EGU General Assembly 2021, online, 19–30 Apr 2021, EGU21-1112, https://doi.org/10.5194/egusphere-egu21-1112, 2021.