Abstract
Gravity field modelling in coastal region faces challenges due to the degradation of the quality of altimeter data and poor coverage of gravimetric measurements. Airborne gravimetry can provide seamless measurements both onshore and offshore with uniform accuracies, which may alleviate the coastal zone problem. We study the role of airborne data for gravity field recovery in a coastal region and the possibility to validate coastal gravity field model against recent altimetry data (CryoSat-2, Jason-1, and SARAL/Altika). Moreover, we combine airborne and ground-based gravity data for regional refinement and quantify and validate the contribution introduced by airborne data. Numerical experiments in the Gippsland Basin over the south-eastern coast of Australia show that the effects introduced by airborne gravity data appear as small-scale patterns on the centimetre scale in terms of quasi-geoid heights. Numerical results demonstrate that the combination of airborne data improves the coastal gravity field, and the recent altimetry data can be potentially used to validate the high-frequency signals introduced by airborne data. The validation against recent altimetry data demonstrates that the combination of airborne measurements improves the coastal quasi-geoid, by ~ 5 mm, compared with a model computed from terrestrial and altimetry-derived gravity anomalies alone. These results show that the recently released altimetry data with relatively denser spatial resolutions and higher accuracies than older altimeter data may be beneficial for gravity field model assessment in coastal areas.
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1 Introduction
Accurate knowledge of coastal gravity field is of importance for geodetic mean dynamic topography (MDT) modelling, which is useful for studying coastal ecosystem processes and sea level change, as well as facilitating other offshore activities (Pugh and Woodworth 2014; Rio et al. 2011, 2014). Improvements to coastal quasi-geoid/geoid model also facilitate the use of geodetic MDT for height datum unification (Featherstone and Filmer 2012; Filmer and Featherstone 2012; Filmer et al. 2018). However, coastal zones often present multiple challenges for quasi-geoid/geoid recovery (e.g. Hwang et al. 2006; Hirt 2013; Ophaug et al. 2015). First, the satellite altimeter-derived data contain larger errors in coastal zones than in open seas, due to the land and calm water contamination on the return waveforms and degradation of the applied corrections (e.g. atmospheric signals and tides) (Deng and Featherstone 2006; Cipollini et al. 2010; Andersen and Scharroo 2011). The poor data coverage in coastal boundary exacerbates this problem, which remains a barrier on coastal quasi-geoid/geoid determination (e.g. Claessens 2012; Featherstone 2010; Huang 2017). Moreover, inconsistency problems remain among the measurements on land, coastal zone, and open sea, in terms of accuracies and spatial resolutions (e.g. Hipkin et al. 2004; Woodworth et al. 2012; Wu et al. 2017a).
Due to the lack of sufficient data, it is difficult to improve the coastal gravity field in terms of accuracy and reliability, especially in narrow and shallow water areas, where marine surveys are almost inaccessible (e.g. Olesen et al. 2000; Forsberg et al. 2012a; Jekeli et al. 2013). This coastal zone problem may be allayed with the use of airborne gravimetric survey, which fills the data gap in this area (e.g. Schwarz and Li 1996; Forsberg et al. 2000; Olesen et al. 2002; Barzaghi et al. 2009). The airborne survey supplies seamless gravity measurements over land and sea with uniform accuracies, which is valuable for coastal gravity field modelling (e.g. Forsberg and Kenyon 1995; Andersen and Knudsen 2000; Fernandes et al. 2000; Forsberg et al. 2001, 2012b). Previous investigations showed that airborne measurements had great potential in coastal gravity field refinement (e.g. Kearsley et al. 1998; Bastos et al. 2000; Olesen 2003; Hwang et al. 2006); however, the lack of control data remains a problem for validating the additional signals introduced by airborne data (e.g. McCubbine et al. 2018).
On the other hand, the recent satellite altimetry missions (e.g. CryoSat-2, Jason, and SARAL/Altika) provide much denser and more accurate sea surface heights (SSHs) than traditional radar altimetry ones (e.g. Geosat and ERS-1) (e.g. Sandwell et al. 2013, 2014; Garcia et al. 2014; Verron et al. 2015). In particular, the CryoSat-2 mission with synthetic aperture radar (SAR) and SAR interferometric (SARIn) measurements provides accurate SSH data up to several kilometres from the coast (e.g. Abulaitijiang et al. 2015; Passaro et al. 2016; Bonnefond et al. 2018). As a result, the coastal geodetic MDTs derived from these data approximately agree at several centimetres level with the ocean models and tide gauge-derived MDT data (Ophaug et al. 2015; Idžanović et al. 2017; Andersen et al. 2018). This shows that recent altimetry data may serve as an additional source for coastal gravity field and MDT modelling and validation. Thus, the aim of this study is twofold: first, to investigate the possibility to validate the coastal quasi-geoid/geoid models against recent altimetry data; second, to combine airborne gravity data and heterogeneous terrestrial gravimetry and altimetry measurements for regional quasi-geoid/geoid refinement and quantify and validate the contribution introduced by airborne data.
2 Study area and data
The study area is located over the Gippsland Basin along the south-eastern coast of Victoria in Australia, where a high-resolution airborne gravimetric survey was contracted by the Victoria State Department of Primary Industries as part of studies for a carbon capture and storage project (Martin et al. 2011), see Fig. 1. This airborne survey covers both onshore and offshore areas, so it provides reasonable data coverage for coastal gravity field refinement; see the blue lines in Fig. 1. Besides, surface gravity data are available, derived from the recent land measurements over the mainland of Australia and newly released satellite altimetry-derived gravity anomalies (Featherstone et al. 2018a), see the red dots in Fig. 1. Shipborne gravity measurements are excluded since they are sparse and unreliable (Featherstone 2009).
2.1 Surface gravity anomalies
Terrestrial gravity data used in this study are consistent with that used for computing the recent Australian gravimetric quasi-geoid 2017 (AGQG2017), where the additional ∼ 280,000 land gravity observations were incorporated, compared with the data used for computing AGQG2009 (Featherstone et al. 2018a). Marine gravity data were extracted from the recently released altimetry-derived gravity anomalies (include Jason-1 and CryoSat-2 data), which were computed by the Scripps Institution of Oceanography (University of California) (Sandwell et al. 2014). These gravity data improved the marine gravity field derived from the older altimeter data (e.g. Geosat and ERS-1), by a factor of 2–4 (Sandwell et al. 2013, 2014). The altimetry-derived gravity data are generally accurate to several mGal in open oceans, while this value may decrease to tens of mGal in coastal regions (Sandwell et al. 2014). Land gravity data and altimetry-derived gravity anomalies were merged through the procedures discussed in Featherstone et al. (2011), and the merged grid has a spatial resolution of 1′ × 1′.
2.2 Airborne gravity measurements
An airborne gravimetric survey was conducted by sander geophysics limited (SGL) during November and December 2011 using the airborne inertially referenced gravimeter (AIRGrav) system. This survey area composed of approximately 1/3 onshore area and 2/3 offshore area. This survey contained 11 flights in total to complete 10,523 line km. The traverse lines were northeast-southwest oriented and spaced at 1 km, and a nine km wide strip along the coast was flown at 500 m line spacing, while the tie lines were northwest-southeast oriented and spaced at 10 km. The flight heights ranged from 143 to 362 m above the mean sea level, with an average velocity of approximately 55 m/s (Martin et al. 2011).
Gravity anomalies were calculated by subtracting the GPS-derived aircraft accelerations from the inertial accelerations and corrected for the Eötvös effect. The normal gravity values were removed, and the data were provided at a sample rate of 2 Hz. Off-level corrections were applied to compensate for the instrument tilt, and high-frequency noises were reduced by applying a 35 s half-wavelength cosine tapered low-pass filter (Martin et al. 2011). The gravity data were referenced to the existing Australian Absolute Gravity Datum 2007 (AAGD07) (Tracey et al. 2007), and the geodetic coordinates were referenced to the GRS80 reference ellipsoid and Geocentric Datum of Australia 1994 (GDA94). The ellipsoidal heights were converted to heights above the Australian height datum (AHD) using AUSGeoid09, which is a hybrid gravimetric–geometric model (Featherstone et al. 2011). Nine repeat lines were conducted for quality control, and the overall standard deviation (SD) of the variations of repeat lines was estimated as 0.36 mGal. Moreover, the SD of the differences between measured gravity values at the intersections of tie and traverse lines was computed as 0.35 mGal, which was commensurate with the statistics of the repeat lines (Martin et al. 2011). These airborne gravity data were not used in the recently computed Australian gravimetric quasi-geoid 2017 (AGQG2017) (Featherstone et al. 2018a).
2.3 Satellite altimetry data
The altimeter-derived data are used to assess the coastal gravity field models and validate the additional signals introduced by airborne data. The altimetry data are extracted from radar altimeter database system (RADS, Scharroo et al. 2013) and include seven and half years (2010–2017) of CryoSat-2 data, one full 406-day repeat cycle of Jason-1 geodetic mission data and one year of SARAL/Altika drifting phase data. Cryosat-2 operated in the low-resolution mode (LRM) in this study area, which was identical to the conventional altimeters such as Jason-1. The altimeters on CryoSat-2 and Jason-1 operated in the Ku-band, while it was operating in the Ka-band for SARAL/Altika. Ka-band radar altimeter was proved to give better range precision compared with Ku-band altimeter (Smith 2015; Zhang and Sandwell 2017).
In RADS, 1 Hz observations were derived from the elementary 20 Hz (40 Hz for SARAL) measurements. Each of the altimetry waveform was retracked using the modified Brown retracker (Brown 1977). Contaminated waveforms near the coastal zone that were hard to fit an analytical waveform were discarded and not used for the derivation of 1 Hz observations. For CryoSat-2 and Jason-1, at least 16 of the 20 Hz observations were used to obtain a 1 Hz observation. For SARAL, at least 33 of the 40 Hz observations were used to produce a 1 Hz observation. In addition, range biases between satellites were corrected in RADS. Therefore, the altimetry data obtained from RADS are reliable and of high quality near the coastal zone, although there may be data gaps close to the coastal lines. In the process of deriving the 1 Hz observation, the standard deviation of the inconsistencies between the finally computed 1 Hz observation and original observations provides the estimated error information of altimeter data. The maximum/minimum value of the estimated errors of these data over the local region (the distribution of altimeter data is shown in Fig. 2) is 8/0.6 cm, with a mean magnitude of 4.6 cm.
In this study, the altimeter-derived quasi-geoid heights are computed for validation purpose. It is worth to mention that we focus on the short wavelength features of local gravity field. Hence, after retrieving the SSHs from RADS, we remove the EGM2008 quasi-geoid (Pavlis et al. 2012, 2013) up to degree and order (d/o) 1080 and the full dynamic topography signals from the EGM2008 dynamic ocean topography [DOT, or known as mean dynamic topography (MDT)] model (d/o 180) from the SSHs to derive the residual geometric quasi-geoid heights. It is noticeable that oceanic MDT may be used instead of geodetic MDT to derive independent quasi-geoid heights. However, the focus of this study is on the validation of local gravity field at short wavelengths (< 20 km), while the commonly used MDTs have relatively low resolutions and mainly reflect the spectral contents at longer wavelengths. Thus, the choices of MDTs may have less impact on the validation results. Besides, another reason for using EGM2008 DOT is to be consistent with what has been removed at long wavelengths, i.e. EGM2008 up to d/o 1080 is removed. In this way, the spectral consistency of reference model and MDT used for data preprocessing is ensured, and aliasing problem may be avoided. Further, the data are reduced by the residual terrain model (RTM) corrections (Forsberg and Tscherning 1981; Forsberg 1984), though they are quite small over the local area. Then, the crossover adjustment is applied to reduce the tilts and biases in the geometric quasi-geoid heights. The outliers in the data are removed based on the 3-sigma rule. Finally, a Gaussian filter with a correlation length of 3 km is applied to reduce the high-frequency noises. The residual altimeter-derived quasi-geoid heights are shown in Fig. 2, which range from − 8.4 to 8.5 cm, with a standard deviation of 2.65 cm. The mean value of these data is approximately 0.6 mm, which indicates the tilts and biases are successfully removed.
3 Data preparation
3.1 Terrain effects
Coastal gravity field is recovered within the framework of remove–compute–restore (RCR) methodology (Sjöberg 2005; Omang and Forsberg 2000), where a global geopotential model (GGM) and terrain effects are removed from the surface and airborne gravity data to decrease the signal correlation length and smooth the local gravity signals. Following Featherstone et al. (2018a), EGM2008 is selected as the reference model, and we truncate the d/o of this model to 1080. RTM is applied for recovering the signals that have the shorter wavelengths than the mean distance between the measured gravity data. Shuttle radar topography missions (SRTM) and General Bathymetric Chart of the Oceans (GEBCO) are combined to derive a uniform digital terrain model (DTM) with a spatial resolution of 3″ × 3″ over land and sea, see Fig. 3a. A moving average filter with a window width of approximately 18.33 km is applied to the combined DTM to derive the mean elevation surface (MES) for RTM reduction. In this manner, the constructed MES (Fig. 3b) is in agreement with the spherical degree of the adopted GGM (Hirt 2010). Tesseroids are chosen instead of prisms as the integral elements considering the curvature of the earth (Heck and Seitz 2007). Figure 4 shows the point-wise residual gravity anomalies at the altitude of airborne survey, and the introduction of RTM reduction more significantly reduces the high-frequency signals in land than in ocean. We observe smoothness in the northeast parts of ocean, see the red signals around (147.9°E, 38.1°S), while in other regions the incorporation of RTM corrections does not significantly smooth the local gravity field (even intensify the local signals, e.g. see the blue signals in the southwest parts around (147.1°E, 38.6°S)). From the statistics, we can hardly see significant differences, where the SD of residual data changes from 3.5 to 3.4 mGal with RTM reductions. This may be attributed to the poor quality and low resolution of the bathymetry model as well as the relatively flat local bathymetry.
3.2 Data combination
The airborne observations and surface gravity data are located at different altitudes with heterogeneous spatial coverage and resolutions; thus, prior to gravity field modelling, we need to downward continue (DWC) airborne data to the quasi-geoid and merge them with the ground-based measurements to derive data with a uniform spatial resolution. Following Mccubbine et al. (2018), we use the three-dimensional least squares collocation (LSC) with the logarithmic covariance function for DWC, since it can downward continue airborne measurements and merge them with ground-based data in a single step (e.g. Forsberg 1987, 2002). For DWC, the Bouguer gravity anomaly is chosen for interpolation (Amos and Featherstone 2004), and the residual gravity data are derived by subtracting the GGM components and RTM effects, which are used for computing the empirical spatial covariance. Different data are assumed to be independent, and the scaled diagonal matrices are used to design the full variance–covariance matrix of LSC model. The detailed procedures for DWC and data merging can be referred to Mccubbine et al. (2018).
The merged grid with the airborne, terrestrial, and altimetric gravity data is shown in Fig. 5a, which maps the local gravity field with a spatial resolution of 1′ × 1′. To investigate the contribution of airborne data to the merged gravity anomalies, we also implement the LSC interpolation procedures to derive the grid without the airborne gravity data, see Fig. 5b. Figure 6 shows the difference between the gridded data computed with and without the airborne data, indicating the contribution of airborne data. The additional signals introduced from the airborne data reach a level of roughly 10 mGal, with a SD of 1.3 mGal, displaying more significant signals in coastal areas than in onshore areas. Possible reason may be due to the degradation of quality of altimetry data in coastal areas, whereas airborne gravimetry does not suffer from the coastal zone problem and may provide more accurate gravity field information than altimeter data. On the other hand, the recently surveyed terrestrial gravity data are of high quality and cover onshore regions over the Gippsland Basin, and the additional signals introduced by the airborne data become less significant in land.
4 Results and discussions
4.1 Regional quasi-geoids modelling
We parameterize the coastal gravity field with Poisson wavelets, which are radially symmetric basis functions that have localizing properties both in the spatial and frequency domains; they have been widely used for local gravity field modelling (e.g. Chambodut et al. 2005; Schmidt et al. 2006; Panet et al. 2011). The full definition of Poisson wavelet can be seen in, e.g. Holschneider et al. (2003), Holschneider and Iglewska-Nowak (2007), and Wittwer (2009). The method for gravity field recovery from Poisson wavelets can be referred to, for example, Klees et al. (2008) and Wu et al. (2017b). The order of Poisson wavelets is fixed at three to achieve a balance between fitting the data and obtaining a smooth solution (Chambodut et al. 2005; Panet et al. 2011). The target region extends from 37.5°S to 39.5°S latitude and 146°E to 149°E longitude. We place the Poisson wavelets on a Fibonacci grid on a surface under the topography and keep it parallel with the topography (Tenzer and Klees 2008). The mean distance between Poisson wavelets is chosen as 2.5 km, and the depth of the grid is fixed as 5 km. Since the regional solution derived from Poisson wavelets suffers from the edge effects, the boundary limits of the target area are contracted by 0.25° in all the directions to extract the effective signals. Due to the heterogeneous spatial resolutions and noise properties of different data as well as the inappropriate network design of Poisson wavelets (i.e. the depth and number of Poisson wavelets), the associated normal matrix may become highly ill-conditioned (Wittwer 2009; Panet et al. 2011). The first-order Tikhonov regularization is used to tackle the ill-conditioned problem (Kusche and Klees 2002), and the convergent regularization parameter is estimated by using the Monte Carlo variance component estimation (MCVCE) method (Koch and Kusche 2002; Kusche 2003). Details of regularization parameter estimation can be referred to Wu et al. (2018).
In order to quantify the contribution of airborne gravity data, we compute two regional solutions; the first one is modelled with the merged grid with the airborne gravity data (Fig. 5a), which is denoted as QGland_TSA (gravimetric quasi-geoid over the Gippsland Basin modelled with terrestrial (T), satellite altimetry (S), and airborne (A) gravity data), while the solution modelled only with the surface gravity data (Fig. 5b) is denoted as QGland_TS. The difference between QGland_TSA and QGland_TS shows the contribution of airborne gravity data in terms of quasi-geoid heights, see Fig. 7. These additional signals stemmed from airborne data display as small-scale features on the centimetre scale, which mainly locate in coastal regions. This is consistent with the results from, for example, Forsberg et al. (2012a) and McCubbine et al. (2018). These results show that the airborne data contain signals that cannot be resolved from the surface gravity data alone, which may contribute to local gravity field recovery. Moreover, we observe more significant signals occurring in coastal areas than in land, and the possible reason may be due to the degradation of quality of altimetry-derived gravity anomalies in coastal areas.
4.2 Validation and comparison
4.2.1 Validation against GPS/levelling data
Local GPS/levelling data are firstly introduced for model validation and comparison, and the detailed information of local GPS/levelling data can be referred to Featherstone et al. (2018b). The original GPS/levelling data were referred to the Australia height datum (AHD) (Roelse et al. 1971). However, AHD is known to contain systematic errors, where a north–south tilt and regional distortions exist (Featherstone and Filmer 2012). Thus, heights from readjustments of the Australia national levelling network (ANLN) were implemented, which served as an updated version of the levelling data used in 1971 AHD adjustment (Featherstone et al. 2018a). Heights derived from a least square adjustment of ANLN are used, which were corrected for the MDT, derived from the Commonwealth Scientific and Industrial Research Organisation Atlas of Regional Seas 2009 (CARS2009) (Dunn and Ridgway 2002; Ridgway et al. 2002). These data are suitable for quasi-geoid assessment in Australia (Featherstone et al. 2018a).
Validation results with local GPS/levelling data are shown in Fig. 8 and Table 1. Note that we removed the mean values of the misfit between the gravimetric models (both for regional models and GGMs) and local GPS/levelling data. These models deviate from the local GPS/levelling data by tens of centimetres in this area, due to the commission errors of the GGMs and uncorrected systematic errors in gravity data and height systems. Thus, if the mean biases are not removed, the inconsistencies between these models and GPS/levelling data are dominated by the systematic errors, which are undesirable for model comparison. The validation results with GPS/levelling data can hardly demonstrate the contribution of airborne data, and the possible reasons are twofold. First, the GPS/levelling data are sparsely distributed in onshore areas, and consequently, the high-frequency signals introduced by airborne data can be hardly detected by the GPS/levelling data. Moreover, we observe most significant signals concentrate in coastal regions (Fig. 7), e.g. see the red signals in south of Rotamah Island around (147.8°E, 38.0°S) and blue ones located around (147.65°E, 38.2°S), while less significant signals are observed in onshore areas. We notice that the terrestrial gravity data used for computing AGQG2017 have good spatial coverage in onshore areas over the Gippsland Basin (Featherstone et al. 2018a). As a result, terrestrial data alone may be sufficient for local small-scale signals recovery in land, and the contribution from airborne data may become less significant. The existing models are introduced for further comparisons, namely AGQG2017 and five high-order GGMs, i.e. EGM2008, EIGEN-6C4 (d/o 2190) (Förste et al. 2014), GECO (d/o 2190) (Gilardoni et al. 2015), SGG-UGM-1 (d/o 2159) (Liang et al. 2018), and GOCO05c (d/o 720) (Fecher et al. 2017). The statistics in Table 1 show that most gravimetric quasi-geoid models except GOCO05c show comparable accuracies, i.e. approximately between 9.7 and 10.4 cm. Due to the limited accuracy of local GPS/levelling data, these models cannot be discriminated (Featherstone et al. 2018a, b). The accuracy of GOCO05c decreases by approximately 3 cm compared with other models, and this may be due to the unrecovered small-scale signals of this model, since the full d/o of GOCO05c is truncated to 720.
4.2.2 Validation against altimeter-derived data
The satellite altimeter-derived quasi-geoid heights can be used to assess the performance of quasi-geoid model in oceanic areas, e.g. see Lieb et al. (2016). The validation of coastal gravity field using altimeter-derived data may be more challenging than that in open seas, since the quality of satellite altimetry data is typically suspicious close to coast. However, the recent altimetry data are denser and more accurate than the traditional data, which may be used as the validation data in coastal areas. The additional signals introduced from airborne data are validated against the CryoSat-2, Jason-1, and SARAL/Altika data, where only the signals located inside the airborne survey are assessed, and 1701 point-wise altimeter-derived quasi-geoid heights are used. The maximum/minimum value of the estimated errors of these 1701 point-wise altimetry data is 7/1 cm, with a mean magnitude of 3.9 cm. It is noticeable that we find a mean value approximately of 0.97 m when comparing AGQG2017 with altimetry data, which is due to the applied zero-order term in computing AGQG2017, and we remove this value for model comparison. The validation results are shown in Fig. 9 and Table 2, and the SD of the misfit between altimeter-derived quasi-geoid heights and gravimetric quasi-geoid decreases from 0.028 to 0.023 m, when validating QGland_TS and QGland_TSA, respectively. Moreover, the combination of airborne data reduces the max/min value of the misfit between the altimeter-derived data and gravimetric quasi-geoid, by a magnitude of several centimetres, see Table 2. Figure 9 shows that the incorporation of airborne data prominently improves the quasi-geoid in coastal areas, especially in areas around (147.5°E, 38.2°S) and (147.6°E, 38.5°S), which is in line with the contribution of airborne data to local gravimetric quasi-geoid.
The validation results show that the recent altimetry data can be potentially used to validate the high-frequency signals introduced by airborne data. Moreover, these altimetry data can be used to distinguish the qualities of different models, which may be beneficial for coast gravity field model assessment, especially in regions lack of control data. These results also demonstrate that the combination of airborne data improves the coastal gravity field, which is consistent with the previous study, e.g. see Hwang et al. (2006). However, we observe undesirable edge effects that affect the quality of QGland_TSA, see the red signals around (148.0°E, 38.3°S) and (148.2°E, 38.0°S) in Fig. 9a. This demonstrates the quality of solution computed with airborne gravity data may become less reliable close to the edge of airborne survey; even we used DWC for merging heterogeneous data at various altitudes to derive the data with a uniform resolution.
The comparisons with other existing models show that QGland_TSA is of highest quality. QGland_TS, AGQG2017, and EGM2008 have comparable accuracies, and all these three models are worse than QGland_TSA, by the magnitudes of approximately 5–8 mm. We introduce the propagated error information of EGM2008 and AGQG2017 (see Fig. 10) for validation. The EGM2008 commission errors are composed of low- and high-degree errors. The low-degree ones were estimated using a satellite-only model through error propagation, while the high-degree errors were computed through a surface integral formula using the calibrated gravity anomalies (Pavlis et al. 2012). The error information of AGQG2017 was computed by using the EGM2008 commission errors and estimated errors of ground-based gravity data (Featherstone et al. 2018a). As shown in Fig. 9a, c, the comparison between QGland_TSA and AGQG2017 shows the former is particularly better in coastal areas, e.g. in regions around (147.4°E, 38.3°S) and (147.1°E, 38.6°S), where larger misfit between the altimeter-derived quasi-geoid heights and AGQG2017 are observed. The associated errors of AGQG2017 range from 4.2 to 5.9 cm in this area, with a mean value of 4.7 cm (Fig. 10a). The validation results are shown to be in general agreement with the estimated errors of AGQG2017, where the prominent errors concentrate along the coastline. Different data preprocessing procedures and methods for parameterization partly account for the differences between QGland_TSA and AGQG2017. For instance, QGland_TSA is recovered from Poisson wavelets, while AGQG2017 was computed from a modified Stoke integral. However, the incorporation of airborne data may be the main reason that QGland_TSA outperforms AGQG2017, since AGGA2017 was computed without combining the airborne data in this region, while the comparison between EGM2008 and QGland_TSA shows that the latter has significant better performances over areas around (147.5°E, 38.5°S) and (147.7°E, 38.3°S). The associated errors of EGM2008 range from 4.3 to 6.4 cm, with a mean value of 4.9 cm. The validation results of EGM2008 using altimeter-derived quasi-geoid heights agree with the estimated errors of EGM2008 (Fig. 10b), where the significant errors are observed along coastal regions. The combination of local airborne gravity data significantly reduces these errors in coastal zones. Similarly, the difference between QGland_TSA and EGM2008 is mainly attributed to the different modelling techniques and the additional signals introduced from the incorporation of recently surveyed ground-based data and airborne measurements.
The accuracies of EIGEN-6C4, GECO, and SGG-UGM-1 are between 3.4 and 3.7 cm, all of which are worse than the four models discussed above. EIGEN-6C4 shows prominent discrepancies with the altimeter-derived data over the coastal areas. The results derived from GECO and SGG-UGM-1 show similar patterns, where large errors occur at south of 38.4°S. We notice that the mean bias between EIGEN-6C4 and altimeter-derived quasi-geoid heights is approximately 10 cm, while we do not observe this bias from the comparisons with EGM2008 or models developed with EGM2008 (i.e. QGland_TSA, QGland_TS, AGQG2017, GECO, and SGG-UGM-1). Possible reason may be due to the selection of reference model in altimeter data preprocessing, where we use EGM2008 as the reference model. Consequently, the computed altimeter-derived data may show more similar properties as EGM2008 than as EIGEN-6C4. Those developed by combining GOCE data and EGM2008 (i.e. GECO and SGG-UGM-1) do not demonstrate comparable performances as EGM2008 alone. This is particularly prominent in the southwest parts, see Fig. 9f, g. The accuracies of GECO and SGG-UGM-1 decrease by 0.8 and 0.5 cm, respectively, compared with EGM2008. GOCO05c is of worst quality, and its accuracy decreases to 4.8 cm.
4.3 Coastal mean dynamic topography determination
Further, we investigate the possibility to improve the coastal MDT using the quasi-geoid computed with airborne gravity data. The geodetic MDT is computed as the difference between mean sea surface (MSS) and geoid/quasi-geoid. The DTU15MSS is chosen as the MSS, provided as the gridded data with a spatial resolution of 1′ × 1′ (Andersen et al. 2015). Considering that QGland_TSA, QGland_TS, AGQG2017, and EGM2008 have better performances than other models when validated against the altimeter-derived data, we compute local MDTs based on these four models. We notice that the gridded gravity data for computing QGland_TSA, QGland_TS, and AGQG2017 have the spatial resolutions of 1′ × 1′, which are consistent with the resolution of DTU15MSS. Moreover, considering that the application of dedicated filtering to smooth the raw MDT may be not entirely satisfactory because of the unclear loss of signals (e.g. Becker et al. 2014), we do not apply the filtering procedure and the raw MDTs are used for comparison.
The MDTs computed based on QGland_TSA, QGland_TS, AGQG2017, and EGM2008 are denoted as MDTQGland_TSA, MDTQGland_TS, MDTQGland_AGQG2017, and MDTQGland_EGM2008, respectively, see Fig. 11. These MDTs show similar patterns over the Gippsland Basin, although observable differences appear among different MDTs, especially in the northern parts. However, because of the lack of in situ observations, the accuracies of different MDTs cannot be quantified. These MDTs show considerably smooth patterns in most areas, indicating the small change of local sea surface topography. However, extreme values are observable along the coastal areas; see these features like mass blocks in Fig. 11. These values are typically identified as errors due to the poorly modelled coastal quasi-geoid and uncorrected errors in the MSS, e.g. see Hipkin et al. (2004) and Wu et al. (2017b). These extreme values are nearly unchanged even when the airborne data are used for coastal quasi-geoid improvement. Thus, the computed MDTs may significantly suffer from the uncorrected errors in the adopted MSS, especially in regions close to coast (Andersen et al. 2010; Andersen and Scharroo 2011). The errors in MDTs are generally consistent with the DTU15MSS error information shown in Fig. 12, where significant errors concentrate along the coast and reach the magnitude of several centimetres. It is noticeable that the displayed DTU15MSS error in Fig. 12 is only the interpolation error and cannot be regarded as the formally propagated error, and the actual MSS error is likely larger than the interpolation error (e.g. Andersen and Knudsen 2009).
It is noticeable that the altimeter-derived data in Sect. 2.3 may be used for refining the coastal geodetic MDT. In fact, the incorporation of recent altimeter data may improve the consistency between coastal MDT and tide gauge-derived MDT data and ocean MDT (Ophaug et al. 2015; Idžanović et al. 2017). However, the altimeter-derived data that are very close to coast were screened out since the waveforms of these data are highly contaminated. As a result, data gaps exist close the coastal lines, see Fig. 2. Thus, the altimeter-derived data in Sect. 2.3 cannot be directly used for MDT refinement over the regions that are close to coastlines. Moreover, due to the limited resolutions of these recent altimeter data, these data alone may be not enough for high-resolution MDT determination.
5 Conclusions
We investigate the role of airborne gravity data in coastal gravity field modelling, in particular, the possibility of validating the coastal quasi-geoid/geoid through the recent altimetry data (CryoSat-2, Jason-1, and SARAL/Altika) is investigated. Moreover, we combine airborne gravimetric measurements and heterogeneous ground-based gravity data for regional refinement and quantify and validate the contribution introduced by airborne data.
A coastal region in the Gippsland Basin over the south-eastern coast of Australia is chosen as a case study, where a high-resolution airborne gravimetric survey that covers both onshore and offshore areas is available. Numerical experiments show that the effects introduced by airborne gravity data display as small-scale patterns on the centimetre scale in terms of quasi-geoid heights, which mainly locate along the coastal areas. Evaluation of the model computed with airborne measurements using local GPS/levelling data can hardly detect the high-frequency signals introduced by airborne data, due to the sparsely distribution of local GPS/levelling data. On the other hand, the validations of different models against the recent altimeter-derived quasi-geoid heights demonstrate that the incorporation of airborne data improves the local quasi-geoid in coastal areas, compared with the one derived from ground-based data alone. By combining airborne data for modelling, the SD of the misfit between the altimeter-derived data and modelled gravimetric quasi-geoid decreases from 2.8 to 2.3 cm. These results indicate that the recent altimeter data may be useful for gravity field model assessment in coastal areas, especially in regions lack of control data. Further comparisons with the existing models show that the solution computed by merging airborne, terrestrial, and altimetric gravity data is of highest quality, which indicate that the combination of airborne gravity data improves coastal gravity field.
The computed geodetic MDTs based on different gravimetric quasi-geoids demonstrate that errors are still prominent along the coastal areas, even when airborne data are incorporated for local quasi-geoid refinement. This indicates that local coastal MDTs may substantially suffer from the errors in the MSS. Thus, the further work involves for coastal MSS refinement by incorporating recent altimeter data and other data sources (e.g. the mean sea level records derived from tide gauge observations).
Data availability
The airborne gravity data are assessed from http://earthresources.vic.gov.au/earth-resources/victorias-earth-resources/carbon-storage/about-carbon-capture-and-storage/archive/About-the-CarbonNet-Project/airborne-gravity-survey. Altimetric gravity anomalies were computed by the Scripps Institution of Oceanography, which are available at http://topex.ucsd.edu/marine_grav/mar_grav.html. Altimetry data for gravity field model assessment were obtained from radar altimeter database system (RADS) and are freely available through http://rads.tudelft.nl/rads/rads.shtml. AGQG2017 and its error information are available at https://s3-ap-southeast-2.amazonaws.com/geoid/. EGM2008 and its associated error grid are available from https://earth-info.nga.mil/GandG/wgs84/gravitymod/egm2008/egm08_wgs84.html, while other global geopotential models can be publicly accessed from http://icgem.gfz-potsdam.de/home. DTU15MSS and its associated error grid are available on https://ftp.space.dtu.dk/pub/DTU15/1_MIN/.
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Acknowledgements
The authors would like to give sincerest thanks to the three anomalous reviewers for the beneficial suggestions and comments, which are of great value for improving the manuscript. The authors also thank the Editor and Associate Editor for their kind assistances and constructive comments. Thanks to Prof. Roland Klees and Dr. Cornelis Slobbe from Delft University of Technology for kindly providing their original software. We gratefully acknowledge the CarbonNet Project Airborne Gravity Survey over Gippsland contracted by Department of Primary Industries of Victoria State in Australia. This study was supported by the Natural Science Foundation of Jiangsu Province, China (No. BK20190498), the Fundamental Research Funds for the Central Universities (No. 2018B07314), the State Scholarship Fund from Chinese Scholarship Council (No. 201306270014), the National Natural Science Foundation of China (Nos. 41830110, 41931074), the Open Research Fund Program of the State Key Laboratory of Geodesy and Earth’s Dynamics (No. SKLGED2018-1-2-E), and the Key Laboratory of Geospace Environment and Geodesy, Ministry of Education, Wuhan University (No. 17-01-09).
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All the authors have contributed to designing the study and writing the manuscript. YW and AA initiated the study, designed the numerical experiments, and wrote the manuscript. WF, JM, and OA provided the data and supplied beneficial suggestions. YW finalized the manuscript. All authors read and approved the final manuscript.
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Wu, Y., Abulaitijiang, A., Featherstone, W.E. et al. Coastal gravity field refinement by combining airborne and ground-based data. J Geod 93, 2569–2584 (2019). https://doi.org/10.1007/s00190-019-01320-3
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DOI: https://doi.org/10.1007/s00190-019-01320-3