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6. Dynamic Estimation of the Wet Path Delay Vertical Gradients From ERA5 for Satellite Altimetry

Author

Fernandes, M. Joana and Vieira, Telmo

Abstract

The retrieval of surface heights from satellite altimetry requires accurate knowledge of the wet path delay (WPD), accounting for the atmospheric water vapor and cloud liquid water effects in the altimeter measurements. In addition to its large horizontal space–time changes, the WPD has a strong and variable vertical gradient. The combination of WPD from different sources, such as those from microwave radiometers (MWRs), numerical weather models (NWMs), and global navigation satellite systems (GNSSs), originally provided at different altitudes, calls for accurate determination of the WPD height gradient, difficult to model, and predict with mathematical expressions. To tackle this problem, this study proposes a dynamic estimation of this effect by using WPD vertical profiles from the ERA5 model. To this end, global grids of representative WPD profiles at $2^{\circ } \times 2^{\circ }$ spacing and 6-h intervals, satisfying a set of conditions, are first computed, and later used for interpolating, in space and time, the WPD vertical gradient. The method is tuned for the conversion of WPD from upper to lower and more variable levels. For the application of combining different WPD sources to estimate the wet tropospheric correction of satellite altimetry observations, the methodology is validated by comparing the GNSS-derived WPD at station elevation with nearby MWR observations at sea level. Results show that, compared with the use of mathematical modeling of constant or varying coefficients, this conducts in a significant reduction in the root mean square (rms) error of 1–8 scm, depending on station height.

Published
2024
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7. Impact Analysis of Global Warming on Wet Path Delay Over the Satellite Altimetry Era (1993–2022)

Author

Vieira, Telmo, Aguiar, Pedro, Lazaro, Clara, Vasconcellos, Bernard, and Fernandes, M. Joana

Abstract

Thirty years of satellite radar altimetry allow the monitoring of sea-level changes at a global scale. The accurate determination of these changes relies directly on how accurately the wet path delay (WPD) in the altimeter observations, mostly due to tropospheric water vapor (WV) content, is estimated. The Clausius–Clapeyron (CC) relation predicts a 7% rise in atmospheric WV for every 1 °C of warming. Building upon this relationship, this study analyzes the impact of global warming on WPD over the satellite altimetry record (1993–2022). Near surface temperature (T2m) and total column water vapor (TCWV) provided by the European Centre for Medium-Range Weather Forecasts (ECMWF) ReAnalysis 5 (ERA5) have been analyzed. Results reveal that global land-ocean temperature has increased at an average rate of 0.23 °C/decade and, in close association, TCWV has increased at a rate of 0.37 mm/decade. For the global ocean, these trends are 0.18 °C and 0.43 mm per decade, respectively. This shows that, per 1 °C of warming, TCWV increases at an average rate of 7% globally (CC relation) and 9% over the global ocean, with respect to its global mean for the study period. Global warming over these 30 years has been responsible for an average increase in TCWV of 1.3 mm over oceans, representing an increase of 8 mm in WPD (0.26 mm/year), equivalent to 1.4 cm (9%) per 1 °C of warming. This study brings crucial findings on the impact of global warming in satellite altimetry, addressing, in particular, physical signals that should not be misled with drifts.

Published
2024
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11. Satellite Altimetry: Sailing Closer to the Coast

Author

Vignudelli, Stefano, Cipollini, Paolo, Gommenginger, Christine, Gleason, Scott, Snaith, Helen M., Coelho, Henrique, Fernandes, M. Joana, Lázaro, Clara, Nunes, Alexandra L., Gómez-Enri, Jesus, Martin-Puig, Cristina, Woodworth, Philip, Dinardo, Salvatore, Benveniste, Jérôme, and Tang, DanLing, editor

Published
2011
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12. Satellite Altimetry in Coastal Regions

Author

Cipollini, Paolo, primary, Benveniste, Jérôme, additional, Birol, Florence, additional, Fernandes, M. Joana, additional, Obligis, Estelle, additional, Passaro, Marcello, additional, Strub, P. Ted, additional, Valladeau, Guillaume, additional, Vignudelli, Stefano, additional, and Wilkin, John, additional

Published
2017
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15. Integration of SIRGAS-CON data in the estimation of the Wet Tropospheric Correction for Latin America Coastal Altimetry

Author

Prado, Anderson, Pires, Nelson, Vieira, Telmo, and Fernandes, M. Joana

Abstract

Satellite Altimetry is one of the main techniques for observing the oceans on a global scale and has contributed to the knowledge of the Mean Sea Level (MSL) and its variations. The main measurement of altimetric satellites is the distance between the satellite and the ocean surface (Range), which is incorrect owing to errors caused by the interaction of the signal with the atmosphere and the sea surface, requiring corrections to account for these effects. The troposphere is responsible for most of these errors, caused by its dry and wet components. The Dry Tropospheric Correction (DTC) is mainly due to atmospheric gases and pressure, being already well established and modeled with high accuracy. Oppositely, the Wet Tropospheric Correction (WTC), caused mainly due to the water vapor present in the troposphere, is much more variable in space and time than the DTC, therefore, more difficult to model. The altimetric satellites are equipped with instruments called Microwave Radiometers (MWR), which measure the amount of water vapour under the satellite path, providing information for the estimation of the WTC. The MWR works well in the open ocean, the surface for which the instrument has been designed, and for which the retrieval algorithms are often tuned, but it fails in coastal zones and inland waters, due to the presence of land in the MWR footprint, and also in areas where ocean ice and heavy rain occur. In view to recover the WTC in these regions, the GNSS (Global Navigation Satellite System) derived Path Delay Plus (GPD+) method, developed by the University of Porto, uses Zenith Tropospheric Delays (ZTD) from GNSS global and regional networks’ stations combined with other sources of information, such as valid on-board MWR measurements, Scanning Image Microwave Radiometers (SI-MWR) and Numeric Weather Models (NWM) from the European Center for Medium-Range Weather Forecasts (ECMWF), to estimate this correction with high accuracy all over the planet. The International GNSS Service (IGS) network, used by GPD+, has GNSS stations spread across the globe, but the coverage is not dense enough, with regions where there are few or no stations. Regional networks are used in order to increase the number of stations and the amount of information. GPD+ currently uses the regional networks EUREF Permanent Network (EPN) and SuomiNet, both located in the northern hemisphere. In order to densify the existing GNSS dataset used in GPD+, it is necessary to add new stations, mainly in the southern hemisphere, in regions such as South America, Africa and Oceania. This work aims to exploit the Latin America and Caribbean SIRGAS-CON network and its potential for densification of the GPD+ input dataset in this region. The accuracy and stability of the WTC derived from SIRGAS-CON ZTD were analyzed, by comparison with WTC from IGS ZTD and ERA5 NWM, and the stations that meet GPD+ requirements were selected for the WTC computation by the algorithm. The WTC computed by GPD+ with and without data from SIRGAS-CON stations were compared with the GNSS-derived WTC, by means of a non-independent and non-collocated comparison at altimetry points from CryoSat-2, Sentinel-3A and Sentinel-3B, in the Latin America and Caribbean regions. The results show that the RMS of the WTC differences for the solution with SIRGAS-CON stations is lower than the solution without SIRGAS-CON stations, for the three satellites, mainly in coastal zones, reaching up 2 mm, which indicates an improvement in the algorithm performance after the addition of the new network. An independent evaluation with data from radiosondes is currently in progress. It is expected that the results of this second evaluation are in line with the results obtained so far, confirming the positive impact of the SIRGAS-CON ZTD in the estimations of the GPD+ WTC in the densified regions.

Published
2022
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16. Synergistic use of the Sentinel-3A SRAL/MWR and SLSTR Sensors for the Wet Tropospheric Correction Retrieval

Author

Aguiar, Pedro, Vieira, Telmo, Lázaro, Clara, and Fernandes, M. Joana

Abstract

The computation of sea surface height measurements from satellite altimetry is nowadays a straightforward procedure, enabling sea level variation studies globally. Amongst the various range corrections that need to be applied to the range measured by the altimeter, the wet tropospheric path delay is still one of the most significant error sources. The most accurate way to retrieve the corresponding wet tropospheric correction (WTC) is through the measurements of microwave radiometers (MWR) on board altimetry missions, collocated with those from the altimeter. For the altimeter reference missions, three-band MWR have been used, with frequency bands around 18 GHz, 23 GHz and 36 GHz. In the case of the dual-band MWR on board European Space Agency’s (ESA) missions, the lack of the lowest frequency channel, which provides mainly information on the surface emissivity and its contribution in the measured MWR brightness temperatures (TB), is currently taken into account by considering additional parameters, namely the altimeter backscatter coefficient, σ0, the sea surface temperature (SST), and the atmospheric temperature vertical decrease rate (γ800). Although the altimeter σ0 parameter is collocated with the MWR measurements, the SST is currently extracted from external static seasonal tables. Recent studies show that the use of a dynamic SST extracted from Numerical Weather Models (ERA5) improves the WTC retrieval, whereas the γ800 parameter provides redundant information. The Copernicus Sentinel-3 mission payload, besides the Synthetic Aperture Radar Altimeter (SRAL) and MWR sensors, includes the Sea and Land Surface Temperature Radiometer (SLSTR), among other collocated sensors, from which gridded SST observations are derived over ocean, simultaneously with observations from the SRAL and MWR sensors. In this context, the objective of the present work is the development of a synergistic approach for the ESA Sentinel-3 mission between the SRAL and MWR sensors with the SLSTR instrument. The aim is to derive the SST measurement from the SLSTR sensor for each SRAL observation and assess its impact in the WTC retrieval over open ocean, thus removing the need for the extraction of the SST parameter from external sources. In a first stage, the SLSTR-derived SST are evaluated against the ERA5 model; their impact in the WTC retrieval is assessed in a second stage. The results show that the use of the SLSTR-derived SST, compared to those from ERA5, has no significant impact on the WTC retrieval over open ocean, both globally and regionally. Thus, for the WTC retrieval, there seems to be no advantage in having collocated SST and altimeter and radiometer observations. Additionally, this study reinforces that the use of dynamic SST leads to a significant improvement over the current Sentinel-3 WTC operational algorithms.

Published
2022
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17. Enhanced GPD+ wet tropospheric corrections for the Copernicus Sentinel-3 missions

Author

Fernandes, M. Joana, Lázaro, Clara, and Vieira, Telmo

Abstract

Amongst its instruments, the Copernicus Sentinel-3 (S3) missions carry the Synthetic Aperture Radar Altimeter (SRAL) for precise sea surface height (SSH) observations and its companion Microwave Radiometer (MWR) for the retrieval of the path delay in the altimeter range caused by the presence of water vapour and cloud liquid water in the atmosphere. In the scope of an activity sponsored by the European Organization for the Exploitation of Meteorological Satellites (EUMETSAT), the University of Porto (UPorto) has been developing an improved WTC for the S3 missions. This improvement is accomplished by means of GPD+, Global Navigation Satellite Systems (GNSS)-derived Path Delay Plus, an algorithm developed at UPorto to retrieve enhanced WTC for radar altimeter missions. The requested improvement is particularly relevant over surfaces where the WTC from the on-board MWR is not available or is invalid due to e.g. the presence of land or ice in the large MWR footprint, such as coastal zones, inland waters and high latitudes. GPD+ is a data combination procedure (Objective Analysis), where valid observations from the on-board radiometer are combined with external measurements from GNSS and imaging radiometers (SI-MWR), to obtain new WTC estimates for all altimeter points for which the Baseline MWR WTC is invalid. In this way, GPD+ preserves the properties of the best available WTC, from the on-board MWR, and further extends this correction to regions and epochs where and when the former is not valid. To ensure the continuity and consistency of the corrections, all input data used in GPD+ undergo various quality checks and calibration procedures. The various MWR (both the on-board and external SI-MWR) are calibrated against the Special Sensor Microwave Imager/Sounder(SSMI/S), considered a stable radiometric reference. The corrections have been assessed by comparisons with other WTC sources: radiometers, GNSS and atmospheric models from the European Centre for Medium range Weather Forecasts (ECMWF). The GPD+ WTC validation includes analysis of sea level anomaly (SLA) along-track variance differences and SLA Root Mean Square (RMS) differences at crossovers (mean cycle values, function of latitude and function of distance from coast). This paper presents the most recent results of the GPD+ WTC for Sentinel-3A and Sentinel-3B, since the start of each mission until April 2021. The main features of the S3 GPD+ WTC include: are continuous and consistent corrections, valid over all surface types; are calibrated against the SSMI/S dataset, taken as reference; improve data coverage, mostly in coastal and polar regions, and fill existing gaps in the valid MWR observations; are improved WTC both with respect to the Baseline MWR WTC for each satellite and to the ECMWF model-derived WTC. The operational provision of the corrections is being implemented, with predicted inclusion in the S3 SRAL/MWR Level 2 products starting in mid-2022.

Published
2022
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18. Exploitation of the ENA Ground-Based Water Vapour Radiometers in Satellite Altimetry

Author

Vasconcellos, Bernard, Lázaro, Clara, Vieira, Telmo, and Fernandes, M. Joana

Abstract

Satellite altimetry has become a standard tool for many Earth Observation studies applied to sea, glaciers, rivers, inland waters and lakes, in order to measure the height of a water body above a reference ellipsoid. The signal emitted by the altimeter sensor is highly dependent on the wet tropospheric correction (WTC), due to its interaction with water vapour suspended in this atmospheric layer. Since water vapour does not behave as a well-mixed gas, its prediction becomes a delicate task. Therefore, microwave radiometers are on board the altimeter satellites in order to determine the WTC very accurately over open-ocean. Despite the ability of this passive sensor to produce collocated measurements with the altimeter, other sources of WTC are needed in locations where observations are invalidated due to the presence of non-ocean surfaces in its footprint, such as in coastal areas and high latitudes. This study aims to investigate ground-based radiometers (MWRGB) as a reliable source of water vapour measurements for deducing the WTC of altimetric observations. For this purpose, the WTC from the MWRGB is assessed by comparison with other four external WTC sources: (1) microwave radiometers on board (MWROB) altimetry missions such as Sentinel-3 A and B, SARAL/AltiKa, and Jason-3; (2) Global Navigation Satellite Systems (GNSS); (3) radiosonde (RS); and (4) ECMWF (European Centre for Medium-Range Weather Forecasts) - ERA5 atmospheric model. The first three comparisons can be collocated or not while the latter is collocated through spatial and temporal interpolation. Among all the comparisons, the only one that is not independent is the comparison with radiosonde, since the information provided by this source is also introduced in the MWRGB retrieval algorithms. MWRGB from one observatory of the Atmospheric Radiation Measurements (ARM) user facility have been used in this study, which is the ENA (Eastern North Atlantic). In addition, retrievals from two ARM algorithms were used in order to evaluate which one best suits the needs of Satellite Altimetry – NN or MWRRETV2. For the ENA observatory, collocated comparisons, or up to 40 km, show RMS of WTC differences in the range 1.02 cm - 1.41 cm. The collocated comparison with ERA5 show RMS of 1.09 cm - 1.19 while the comparison with GNSS, which is non-collocated at only 51 m, shows a higher value of 1.41 cm. Furthermore, the comparisons with MWROB up to 40 km present an RMS in the range of 1.02 cm - 1.30 cm. For the comparison with RS, which is non-collocated at 89 km, an RMS of nearly 2.37 cm is found, which may be explained by the large distance between the two datasets, close to the limit of the WTC spatial correlation scale. The intra-algorithm assessment showed that in general the NN and MWRRETV2 algorithms have great similarity in their results, with a variation of RMS of WTC differences in the range of 0 – 2.8 mm. Therefore, for the needs of Satellite Altimetry up to 40 km, the NN algorithm proves to be a reliable source for deducing WTC, due to the near real-time latency of its retrieved data. At last, two neural network algorithms were tuned to estimate the WTC directly from MWRGB brightness temperatures (TB) observations, which are: (WTCGB_2TB) using 2 inputs - TB from both the 23.8 and 30 GHz bands; and (WTCGB_3TB), using 3 inputs – the former two TB with further inclusion of the TB from the 90 GHz band. Thus, the training dataset consisted of 100,000 samples which refer to 1 year of observations, 3 or 2 TB as inputs, and model-interpolated WTC for the same instants as output. An independent assessment for the WTC values retrieved from both algorithms was carried out against GNSS data. WTCGB_2TB presented an RMS of 1.42 cm while the WTCGB_3TB obtained a better performance of 1.34 cm. Furthermore, the comparison with the NN algorithm, for the same period, showed an RMS of 1.41 cm, which was higher than the result found for the WTCGB_3TB.

Published
2022
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19. MAGAL Constellation

Author

Marques, Arlindo, Lázaro, Clara, Fernandes, M. Joana, Melo, Joaquim, G. C. Guerra, André, João, André, Martin, Miguel, Arantes, Miguel, Figueiredo, Paulo, Coelho, Vitor, Borges Carvalho, Nuno, M. Cecilio, Catarina, Martins, Ana, Mashtakov, Yaroslav, Carrolo, Edgar, Fort, Burke, and Tapley, Byron

Abstract

The concept of a small radar altimeter constellation has already been proposed but not yet implemented due to technological limitations or high costs associated with the operation of such a constellation. Yet, some oceanic processes are still poorly studied and understood due to the lack of adequate sampling of the ocean by past and current satellite altimetry missions. With the increase in popularity of the CubeSat concept and the current availability of low-cost and high-performance components, improving the space-time resolution of satellite altimetry with a constellation of small satellites becomes a possible scenario. The MAGAL Constellation is a future constellation of small satellites carrying radar altimeters that aims to improve the understanding of ocean circulation variability in local, regional, and global scales through improving the spatiotemporal resolution of sea surface topography measurements. By operating as a collective unit, the measurements provided by MAGAL are expected to augment those from the current large satellite radar altimeters. Hence, the framework should be collaborative, to better tackle the gaps of the reference programs, improving the collective data products with an enhanced data set over the open ocean, while also targeting the coastal processes. Four main use cases have been selected, for which the sampling of the ocean with higher spatial and temporal resolutions is required: better characterization of the mesoscale variability at local and regional scales to support operational oceanography; eddy detection and tracking; monitoring of marine debris pathways, and the monitoring of the water level of inland water bodies. To achieve these goals, six CubeSat, no larger than 24U, are being considered which, to reduce the launch cost, are all launched simultaneously into the same orbital plane. The orbital characteristics of the constellation have been selected to provide full coverage of the Earth’s surface with a 5-day repetition cycle and distance between adjacent tracks of ~88 km at the Equator. The altitude must be higher than 500 km, to reduce the effect of atmospheric drag, and less than 600 km, due to the restrictions imposed by altimeter and power budget. A sun-synchronous orbit with 97.4° inclination has been selected for repeatability. The separation of the satellites in the orbital plane, as well as orbit corrections, are to be provided by the thruster system. The MAGAL platform will be miniaturized and manufactured in series, minimizing production, operational and launching costs. The design process will take advantage of the new Space 4.0 industry to integrate readily COTS subsystems (navigation, tracking, cooling and propulsion). Profiting from its low cost, replacement of end-of-life satellites (~3 years) can be accommodated in the same or complementary orbital planes. However, the altimeter payload state-of-the-art demands the development of a new era of small, lower power consuming altimeters. The radar altimeter will operate at a frequency of 13 GHz, with a Frequency Modulated Continuous Wave (FMCW) architecture. The FMCW architecture was selected as it has a lower power consumption (20 W consumption for 1 W transmission RF power) than traditional pulsed radar altimeters. For this radar altimeter to work correctly, with an adequate observation footprint, the antenna must be at least 1.5 m diameter deployable dish antenna. The signal will then be received and treated using digital signal processing using a FPGA approach. A Data Analysis Center (DAC) will also be developed based on cloud-based services, surpassing security issues. The DAC will be responsible for storage of acquired data, and processing of those data, including overlay of different layers from multiple sources (e.g. meteorology), in the back-end side, producing scientific and commercial information. A front-end layer will be responsible for displaying processed data in various graphical interfaces, allowing overlaid correlations between data and layers. The project MAGAL Constellation (Nr. 033688) is co-financed by the European Regional Development Fund through COMPETE 2020, LISBOA 2020 and by FCT under the UT Austin-Portugal interface program, and will consider the insights from the European Union agenda for sustainable development, addressing as many fields of action as possible, and adding value alongside the underlying technology development. Besides providing an integrated approach, bringing together the sea’s economy and its sustainable growth into the future, the MAGAL project will contribute to the knowledge advancement in these fields.

Published
2022
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21. Improved Retrieval Methods for Sentinel-3 SAR Altimetry over Coastal and Open Ocean and recommendations for implementation: ESA SCOOP Project Results

Author

Cotton, David, primary, Moreau, Thomas, additional, Roca, Mònica, additional, Gommenginger, Christine, additional, Cancet, Mathilde, additional, Fenoglio-Marc, Luciana, additional, Naeije, Marc, additional, Fernandes, M Joana, additional, Shaw, Andrew, additional, Restano, Marco, additional, Ambrosio, Americo, additional, and Benveniste, Jérôme, additional

Published
2020
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26. Improved sea state bias estimation for altimeter reference missions with altimeter-only three-parameter models

Author

Pires, Nelson, Fernandes, M. Joana, Gommenginger, Christine, Scharroo, Remko, Pires, Nelson, Fernandes, M. Joana, Gommenginger, Christine, and Scharroo, Remko

Abstract

This paper presents an in-depth study concerning the development of a sea state bias (SSB) model designed with three parameters exclusively derived from altimeter data and globally applied to all reference altimeter missions. The proposed technique, first tested for the Jason-1 mission, proves to have a good performance for a wide range of ocean conditions when compared with the state-of-the-art SSB corrections currently in use. In addition to the significant wave height (Hₛ) and wind speed (U₁₀), a third predictor acting as a mediator parameter gathered by the mean wave period (Tz) has been used. Two different empirical algorithms for altimeter ocean wave period have been tested and implemented, improving the SSB model performance in some ocean regions. The methodology relies on nonparametric modulation and statistical techniques based on smoothing splines embedded in a generalized additive model. This SSB modeling approach shows good performance when applied to all reference missions, in particular to TOPEX and Jason-2 missions, slightly reducing the explained variance of sea-level anomaly (SLA) when compared with the established SSB models. The approach is computationally efficient, capable of generating a stable SSB model using a small training data set when little information is available, as is the case with the recent Jason-3 mission. Model performance is assessed by comparison with existing SSB corrections for each reference mission, intercomparisons during the period of the tandem phases, and by SLA variance analysis, providing a consistent set of SSB corrections for the four reference missions.

Published
2018

27. An improved and homogeneous altimeter sea level record from the ESA Climate Change Initiative

Author

Legeais, Jean-Francois, Ablain, Michael, Zawadzki, Lionel, Zuo, Hao, Johannessen, Johnny A., Scharffenberg, Martin G., Fenoglio-Marc, Luciana, Fernandes, M. Joana, Andersen, Ole Baltazar, Rudenko, Sergei, Cipollini, Paolo, Quartly, Graham D., Passaro, Marcello, Cazenave, Anny, Benveniste, Jerome, Legeais, Jean-Francois, Ablain, Michael, Zawadzki, Lionel, Zuo, Hao, Johannessen, Johnny A., Scharffenberg, Martin G., Fenoglio-Marc, Luciana, Fernandes, M. Joana, Andersen, Ole Baltazar, Rudenko, Sergei, Cipollini, Paolo, Quartly, Graham D., Passaro, Marcello, Cazenave, Anny, and Benveniste, Jerome

Abstract

Sea level is a very sensitive index of climate change since it integrates the impacts of ocean warming and ice mass loss from glaciers and the ice sheets. Sea level has been listed as an essential climate variable (ECV) by the Global Climate Observing System (GCOS). During the past 25 years, the sea level ECV has been measured from space by different altimetry missions that have provided global and regional observations of sea level variations. As part of the Climate Change Initiative (CCI) program of the European Space Agency (ESA) (established in 2010), the Sea Level project (SL_cci) aimed to provide an accurate and homogeneous long-term satellite-based sea level record. At the end of the first phase of the project (2010-2013), an initial version (v1.1) of the sea level ECV was made available to users (Ablain et al., 2015). During the second phase of the project (2014-2017), improved altimeter standards were selected to produce new sea level products (called SL_cci v2.0) based on nine altimeter missions for the period 19932015 (https://doi.org/10.5270/esa-sea_level_cci-1993_2015-v_2.0-201612; Legeais and the ESA SL_cci team, 2016c). Corresponding orbit solutions, geophysical corrections and altimeter standards used in this v2.0 dataset are described in detail in Quartly et al. (2017). The present paper focuses on the description of the SL_cci v2.0 ECV and associated uncertainty and discusses how it has been validated. Various approaches have been used for the quality assessment such as internal validation, comparisons with sea level records from other groups and with in situ measurements, sea level budget closure analyses and comparisons with model outputs. Compared with the previous version of the sea level ECV, we show that use of improved geophysical corrections, careful bias reduction between missions and inclusion of new altimeter missions lead to improved sea level products with reduced uncertainties on different spatial and temporal scales. However, there i

Published
2018

29. An improved and homogeneous altimeter sea level record from the ESA Climate Change Initiative

Author

Legeais, Jean-François, primary, Ablain, Michaël, additional, Zawadzki, Lionel, additional, Zuo, Hao, additional, Johannessen, Johnny A., additional, Scharffenberg, Martin G., additional, Fenoglio-Marc, Luciana, additional, Fernandes, M. Joana, additional, Andersen, Ole Baltazar, additional, Rudenko, Sergei, additional, Cipollini, Paolo, additional, Quartly, Graham D., additional, Passaro, Marcello, additional, Cazenave, Anny, additional, and Benveniste, Jérôme, additional

Published
2018
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31. A new phase in the production of quality-controlled sea level data

Author

Quartly, Graham D., Legeais, Jean-François, Ablain, Michaël, Zawadzki, Lionel, Fernandes, M. Joana, Rudenko, Sergei, Carrère, Loren, García, Pablo Nilo, Cipollini, Paolo, Andersen, Ole B., Poisson, Jean-Christophe, Mbajon Njiche, Sabrina, Cazenave, Anny, Benveniste, Jérôme, Quartly, Graham D., Legeais, Jean-François, Ablain, Michaël, Zawadzki, Lionel, Fernandes, M. Joana, Rudenko, Sergei, Carrère, Loren, García, Pablo Nilo, Cipollini, Paolo, Andersen, Ole B., Poisson, Jean-Christophe, Mbajon Njiche, Sabrina, Cazenave, Anny, and Benveniste, Jérôme

Abstract

Sea level is an essential climate variable (ECV) that has a direct effect on many people through inundations of coastal areas, and it is also a clear indicator of climate changes due to external forcing factors and internal climate variability. Regional patterns of sea level change inform us on ocean circulation variations in response to natural climate modes such as El Niño and the Pacific Decadal Oscillation, and anthropogenic forcing. Comparing numerical climate models to a consistent set of observations enables us to assess the performance of these models and help us to understand and predict these phenomena, and thereby alleviate some of the environmental conditions associated with them. All such studies rely on the existence of long-term consistent high-accuracy datasets of sea level. The Climate Change Initiative (CCI) of the European Space Agency was established in 2010 to provide improved time series of some ECVs, including sea level, with the purpose of providing such data openly to all to enable the widest possible utilisation of such data. Now in its second phase, the Sea Level CCI project (SL_cci) merges data from nine different altimeter missions in a clear, consistent and well-documented manner, selecting the most appropriate satellite orbits and geophysical corrections in order to further reduce the error budget. This paper summarises the corrections required, the provenance of corrections and the evaluation of options that have been adopted for the recently released v2.0 dataset (https://doi.org/10.5270/esa-sea_level_cci-1993_2015-v_2.0-201612). This information enables scientists and other users to clearly understand which corrections have been applied and their effects on the sea level dataset. The overall result of these changes is that the rate of rise of global mean sea level (GMSL) still equates to ∼ 3.2 mm yr−1 during 1992–2015, but there is now greater confidence in this result as the errors associated with several of the corrections have be

Published
2017

32. An Accurate and Homogeneous Altimeter Sea Level Record from the ESA Climate Change Initiative

Author

Legeais, Jean-Francois, primary, Ablain, Michaël, additional, Zawadzki, Lionel, additional, Zuo, Hao, additional, Johannessen, Johnny A., additional, Scharffenberg, Martin G., additional, Fenoglio-Marc, Luciana, additional, Fernandes, M. Joana, additional, Andersen, Ole Baltazar, additional, Rudenko, Sergei, additional, Cipollini, Paolo, additional, Quartly, Graham D., additional, Passaro, Marcello, additional, Cazenave, Anny, additional, and Benveniste, Jérôme, additional

Published
2017
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33. A new phase in the production of quality-controlled sea level data

Author

Quartly, Graham D., primary, Legeais, Jean-François, additional, Ablain, Michaël, additional, Zawadzki, Lionel, additional, Fernandes, M. Joana, additional, Rudenko, Sergei, additional, Carrère, Loren, additional, García, Pablo Nilo, additional, Cipollini, Paolo, additional, Andersen, Ole B., additional, Poisson, Jean-Christophe, additional, Mbajon Njiche, Sabrina, additional, Cazenave, Anny, additional, and Benveniste, Jérôme, additional

Published
2017
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34. An Accurate and Homogeneous Altimeter Sea Level Record from the ESA Climate Change Initiative.

Author

Legeais, Jean-Francois, Ablain, Michaël, Zawadzki, Lionel, Zuo, Hao, Johannessen, Johnny A., Scharffenberg, Martin G., Fenoglio-Marc, Luciana, Fernandes, M. Joana, Andersen, Ole Baltazar, Rudenko, Sergei, Cipollini, Paolo, Quartly, Graham D., Passaro, Marcello, Cazenave, Anny, and Benveniste, Jérôme

Subjects
SEA level & the environment, ALTIMETERS
Abstract

Sea Level is a very sensitive index of climate change since it integrates the impacts of ocean warming and ice mass loss from glaciers and the ice sheets. Sea Level has been listed as an Essential Climate Variable (ECV) by the Global Climate Observing System (GCOS). During the past 25 years, the sea level ECV has been measured from space by different altimetry missions that have provided global and regional observations of sea level variations. As part of the Climate Change Initiative (CCI) program of the European Space Agency (ESA) (established in 2010), the Sea Level project (SL_cci) aimed at providing an accurate and homogeneous long-term satellite-based sea level record. At the end of the first phase of the project (2010-2013), an initial version (v1.1) of the sea level ECV has been made available to users (Ablain et al., 2015). During the second phase (2014-2017), improved altimeter standards have been selected to produce new sea level products (called SL_cci v2.0) based on 9 altimeter missions for the period 1993-2015 (https://doi.org/10.5270/esa-sea_level_cci-1993_2015-v_2.0-201612). Corresponding orbit solutions, geophysical corrections and altimeter standards used in this v2.0 dataset are described in details in Quartly et al. (2017). The present paper focuses on the description of the SL_cci v2.0 ECV and associated uncertainty and discusses how it has been validated. Various approaches have been used for the quality assessment such as internal validation, comparisons with sea level records from other groups and with in-situ measurements, sea level budget closure analyses and comparisons with model outputs. Compared to the previous version of the sea level ECV, we show that use of improved geophysical corrections, careful bias reduction between missions and inclusion of new altimeter missions lead to improved sea level products with reduced uncertainties at different spatial and temporal scales. However, there is still room for improvement since the uncertainties remain larger than the GCOS requirements. Perspectives for subsequent evolutions are also discussed. [ABSTRACT FROM AUTHOR]

Published
2017
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35. GPD+ Wet Tropospheric Corrections for CryoSat-2 and GFO Altimetry Missions.

Author

Fernandes, M. Joana and Lázaro, Clara

Subjects
*GLOBAL Positioning System, *MICROWAVE radiometers, *NATURAL satellites, *RADAR altimetry, *REMOTE sensing, *SEA level
Abstract

Due to its large space-time variability, the wet tropospheric correction (WTC) is still considered a significant error source in satellite altimetry. This paper presents the GNSS (Global Navigation Satellite Systems) derived Path Delay Plus (GPD+), the most recent algorithm developed at the University of Porto to retrieve improved WTC for radar altimeter missions. The GPD+ are WTC estimated by space-time objective analysis, by combining all available observations in the vicinity of the point: valid measurements from the on-board microwave radiometer (MWR), from GNSS coastal and island stations and from scanning imaging MWR on board various remote sensing missions. The GPD+ corrections are available both for missions which do not possess an on-board microwave radiometer such as CryoSat-2 (CS-2) and for all missions which carry this sensor, by addressing the various error sources inherent to the MWR-derived WTC. To ensure long-term stability of the corrections, the large set of radiometers used in this study have been calibrated with respect to the Special Sensor Microwave Imager (SSM/I) and the SSM/I Sounder (SSM/IS). The application of the algorithm to CS-2 and Geosat Follow-on (GFO), as representative altimetric missions without and with a MWR aboard the respective spacecraft, is described. Results show that, for both missions, the newWTC significantly reduces the sea level anomaly (SLA) variance with respect to the model-based corrections. For GFO, the new WTC also leads to a large reduction in SLA variance with respect to the MWR-derived WTC, recovering a large number of observations in the coastal and polar regions and full sets of tracks and several cycles when MWR measurements are missing or invalid. Overall, the algorithm allows the recovery of a significant number of measurements, ensuring the continuity and consistency of the correction in the open-ocean/coastal transition zone and at high latitudes. [ABSTRACT FROM AUTHOR]

Published
2016
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36. A Conceptually Simple Modeling Approach for Jason-1 Sea State Bias Correction Based on 3 Parameters Exclusively Derived from Altimetric Information.

Author

Pires, Nelson, Fernandes, M. Joana, Gommenginger, Christine, and Scharroo, Remko

Subjects
*OCEAN waves, *REGRESSION analysis, *SPLINES, *WIND speed, *ALTIMETRY
Abstract

A conceptually simple formulation is proposed for a new empirical sea state bias (SSB) model using information retrieved entirely from altimetric data. Nonparametric regression techniques are used, based on penalized smoothing splines adjusted to each predictor and then combined by a Generalized Additive Model. In addition to the significant wave height (SWH) and wind speed (U10), a mediator parameter designed by the mean wave period derived from radar altimetry, has proven to improve the model performance in explaining some of the SSB variability, especially in swell ocean regions with medium-high SWH and low U10. A collinear analysis of scaled sea level anomalies (SLA) variance differences shows conformity between the proposed model and the established SSB models. The new formulation aims to be a fast, reliable and flexible SSB model, in line with the well-settled SSB corrections, depending exclusively on altimetric information. The suggested method is computationally efficient and capable of generating a stable model with a small training dataset, a useful feature for forthcoming missions. [ABSTRACT FROM AUTHOR]

Published
2016
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40. Atmospheric Corrections for Altimetry Studies over Inland Water.

Author

Fernandes, M. Joana, Lázaro, Clara, Nunes, Alexandra L., and Scharroo, Remko

Subjects
*OCEANOGRAPHY, *ALTIMETRY, *ALTITUDE measurements, *REMOTE sensing, *ALTIMETERS
Abstract

Originally designed for applications over the ocean, satellite altimetry has been proven to be a useful tool for hydrologic studies. Altimeter products, mainly conceived for oceanographic studies, often fail to provide atmospheric corrections suitable for inland water studies. The focus of this paper is the analysis of the main issues related with the atmospheric corrections that need to be applied to the altimeter range to get precise water level heights. Using the corrections provided on the Radar Altimeter Database System, the main errors present in the dry and wet tropospheric corrections and in the ionospheric correction of the various satellites are reported. It has been shown that the model-based tropospheric corrections are not modeled properly and in a consistent way in the various altimetric products. While over the ocean, the dry tropospheric correction (DTC) is one of the most precise range corrections, in some of the present altimeter products, it is the correction with the largest errors over continental water regions, causing large biases of several decimeters, and along-track interpolation errors up to several centimeters, both with small temporal variations. The wet tropospheric correction (WTC) from the on-board microwave radiometers is hampered by the contamination on the radiometer measurements of the surrounding lands, making it usable only in the central parts of large lakes. In addition, the WTC from atmospheric models may also have large errors when it is provided at sea level instead of surface height. These errors cannot be corrected by the user, since no accurate expression exists for the height variation of the WTC. Alternative and accurate corrections can be computed from in situ data, e.g., DTC from surface pressure at barometric stations and WTC from Global Navigation Satellite System permanent stations. The latter approach is particularly favorable for small lakes and reservoirs, where GNSS-derived WTC at a single location can be representative of the whole lake. For non-timely critical studies, for consistency and stability, model-derived tropospheric corrections from European Centre for Medium-Range Weather Forecasts (ECMWF) Re-Analysis ERA Interim, properly computed at surface height, are recommended. The instrument-based dual-frequency ionospheric correction may have errors related with the land contamination in the Ku and C/S bands, making it more suitable to use a model-based correction. The most suitable model-based ionospheric correction is the Jet Propulsion Laboratory (JPL) global ionosphere map (GIM) model, available after 1998, properly scaled to the altimeter height. Most altimeter products provide the GIM correction unreduced for the total electron content extending above the altitude of these satellites, thus overestimating the ionospheric correction by about 8%. Prior to 1998, the NIC09 (NOAA Ionosphere Climatology 2009) climatology provides the best accuracy. [ABSTRACT FROM AUTHOR]

Published
2014
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41. Analysis and Inter-Calibration of Wet Path Delay Datasets to Compute the Wet Tropospheric Correction for CryoSat-2 over Ocean.

Author

Fernandes, M. Joana, Nunes, Alexandra L., and Lázaro, Clara

Subjects
*TROPOSPHERIC circulation, *MICROWAVE radiometers calibration, *RADAR altimetry, *LONG-range weather forecasting, *WATER vapor, *REMOTE sensing
Abstract

Unlike most altimetric missions, CryoSat-2 is not equipped with an onboard microwave radiometer (MWR) to provide wet tropospheric correction (WTC) to radar altimeter measurements, thus, relying on a model-based one provided by the European Center for Medium-range Weather Forecasts (ECMWF). In the ambit of ESA funded project CP4O, an improved WTC for CryoSat-2 data over ocean is under development, based on a data combination algorithm (DComb) through objective analysis of WTC values derived from all existing global-scale data types. The scope of this study is the analysis and inter-calibration of the large dataset of total column water vapor (TCWV) products from scanning MWR aboard Remote Sensing (RS) missions for use in the WTC computation for CryoSat-2. The main issues regarding the computation of the WTC from all TCWV products are discussed. The analysis of the orbital parameters of CryoSat-2 and all other considered RS missions, their sensor characteristics and inter-calibration is presented, providing an insight into the expected impact of these datasets on the WTC estimation. The most suitable approach for calculating the WTC from TCWV is investigated. For this type of application, after calibration with respect to an appropriate reference, two approaches were found to give very similar results, with root mean square differences of 2 mm. [ABSTRACT FROM AUTHOR]

Published
2013
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