Retrieving Sea Level and Freeboard in the Arctic: A Review of Current Radar Altimetry Methodologies and Future Perspectives
Abstract
:1. Introduction
1.1. Scientific and Operational Requirements
1.2. Relevant Altimeter Datasets
2. Waveform Discrimination
2.1. LRM Altimeters
2.1.1. Classical Techniques
2.1.2. Statistical Techniques
2.2. SAR Altimeters
2.2.1. Power-Based Methods
2.2.2. RIP and Waveform Shape-Based Methods
2.2.3. Statistical Techniques
2.3. Validation of Discrimination
2.3.1. Validation with Optical Sensors
2.3.2. Validation with SAR
2.3.3. Validation Through Dedicated Aircraft Campaigns
3. Waveform Retracking
3.1. Waveform Retracking for Ice Floes
3.1.1. LRM Retracking for Ice Floes
3.1.2. Empirical SAR Waveform Retracking for Ice Floes
3.1.3. Physical SAR waveform Retracking for Ice Floes
3.2. Waveform Retracking for Leads
3.2.1. LRM Model for Leads
3.2.2. SAR Retracking for Leads
3.3. Unified Models for Physical Retracking
3.4. Quality Control: Further Editing of Data
3.4.1. Snagging Effect Within Altimeter Data
3.4.2. Azimuth Ambiguity Effect Within SAR Data
3.4.3. Ensuring Consistency in Space and Time
4. Corrections and References Needed for Inferring Precise Geophysical Values
4.1. Determining Sea Level
4.1.1. Atmospheric Corrections
4.1.2. Tides and Mean Sea Surface
4.1.3. Amplitude and Scale Length of Corrections
4.2. Determining Freeboard and Ice Thickness
4.2.1. Interpolating Sea Level Anomaly and Calculating Freeboard
4.2.2. Freeboard to Thickness Conversions
4.2.3. Impact of Snow on Sea-Ice Freeboard and Thickness Retrievals
5. Comparison With In Situ and Airborne Measurements
5.1. Sea Level and Currents
5.2. Freeboard and Sea-Ice Thickness
5.2.1. Freeboard
5.2.2. Sea-Ice Thickness (SIT)
5.2.3. Validation of Algorithms
6. Future Prospects: Expectations and Hopes
6.1. Improvements in Processing
6.2. New Missions with New Capabilities
6.3. Realizing the Potential of SAR Interferometry (SARin)
6.4. Utilising Data Fusion Techniques
6.5. Enhanced in Situ Observations
7. Conclusions
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
Abbreviations
ADCP | Acoustic Doppler Current Profiler | mss | mean square slope |
AEM | Airborne ElectroMagnetic sensor | MSS | Mean Sea Surface |
AGC | Automatic Gain Control | MWR | Microwave Radiometer |
ALES | Adaptive Leading Edge Sub-waveform | MYI | Multi-Year Ice |
ALOS | Advanced Land Observation Satellite | NN | Neural Net |
ATM | Airborne Topographic Mapper | NSIDC | National Snow and Ice Data Center |
BGEP | Beaufort Gyre Exploration Project | OCOG | Offset Centre-Of-Gravity |
BH | Brown-Hayne | OIB | Operation IceBridge |
CCI | Climate Change Initiative | OLCI | Ocean and Land Colour Instrument |
CPOM | Centre for Polar Observation and Modelling | PLRM | Pseudo Low-Rate Measurement |
CryoVEx | Cryosat Validation Experiment | PP | Pulse Peakiness |
DAC | Dynamic Atmosphere Correction | PTR | Point Target Response |
DDA | Delay-Doppler Altimeter | RA | Radar Altimeter |
DOT | Dynamic Ocean Topography | RIP | Range-Integrated Power |
DTC | Dry Tropospheric Correction | SAMOSA | SAR Altimetry MOde Studies and Applications |
ERS | European Remote-sensing Satellite | SAR | Synthetic Aperture Radar |
Envisat | Environmental Satellite | SARin | SAR interferometry |
ESA | European Space Agency | S.D. | Standard Deviation |
FFT | Fast Fourier Transform | SIC | Sea-Ice Concentration |
FYI | First Year Ice | SIT | Sea-Ice Thickness |
GDR | Geophysical Data Record | SK | Stack Kurtosis |
GOCE | Gravity field and steady-state Ocean | SLA | Sea Level Anomaly |
Circulation Explorer | SMMR | Scanning Multichannel Microwave Radiometer | |
GRACE | Gravity Recovery and Climate Experiment | SMOS | Soil Moisture and Ocean Salinity |
ICESat | Ice, Cloud, and land Elevation Satellite | SP | Stack Peakiness |
IMB | Ice Mass Balance | SRAL | Sentinel-3 Radar Altimeter |
LEW | Leading Edge Width | SS | Stack Skewness |
LRM | Low Rate Measurement | SSD | Stack Standard Deviation |
MDT | Mean Dynamic Topography | SSM/I | Special Sensor Microwave/Imager |
MERIS | Medium Resolution Imaging Spectrometer | TES | Trailing Edge Slope |
MODIS | Moderate Resolution Imaging | TFMRA | Threshold First Maximum Retracker Algorithm |
Spectroradiometer | ULS | Upward-Looking Sonar | |
MP | Maximal Power | WTC | Wet Tropospheric Correction |
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Satellite/Altimeter | Dates | Radar Freq. (GHz) | Band- Width (MHz) | Beam- Width () | Repeat Period (days) | Comments |
---|---|---|---|---|---|---|
ERS-1/RA | Jul 1991–Apr 2000 | 13.8 | 330 | 1.3 | 35 | There were also mission phases with 3-day and 168-day repeat orbits. |
ERS-2/RA | Apr 1995–Jun 2003 | 13.8 | 330 | 1.3 | 35 | Onboard data storage was lost in June 2003; limited direct-relay data was available until July 2011. |
Envisat/RA-2 | Mar 2002–Apr 2012 | 13.6 3.2 | 320 160 | 1.3 5.5 | 35 | Operation in S-band ceased in Mar. 2008. Changed to a 27-day repeat orbit in Oct. 2010. |
SARAL / AltiKa | Feb 2013– | 35 | 480 | 0.6 | 35 | Drift orbit from Jul 2016 onwards. |
CryoSat-2/SIRAL | Apr 2010– | 13.6 | 320 | 1.08 × 1.2 | 369 | Slightly elliptical antenna. Operated in SAR mode over sea ice. |
Sentinel-3A/SRAL | Feb 2016– | 13.6 5.4 | 350 320 | 1.35 3.4 | 27 | |
Sentinel-3B/SRAL | Apr 2018– | 13.6 5.4 | 350 320 | 1.35 3.4 | 27 |
Tidal Constituent | Envisat, AltiKa (35-Day Repeat) | Jason-3, Jason-CS/ Sentinel-6 (9.9156-day) | CryoSat-2 (369-Day Repeat) | Sentinel-3A, -3B (27-day Repeat) | IceSAT-2 (91-Day Repeat) |
---|---|---|---|---|---|
M2 | 94.4 | 62.1 | 112.1 | 157.5 | 55.79 |
S2 | Infinite | 58.7 | Infinite | Infinite | Infinite |
K1 | 365.25 | 173.1 | 98.1 | 365.25 | 365.25 |
O1 | 75.1 | 45.1 | 77.1 | 277.0 | 220.1 |
Correction Component | % Missing | Mean (m) | S.D. (m) |
---|---|---|---|
MSS sol.1 (CNES-CLS-15) | 12.8 | 1.72 | 7.13 |
MSS sol.2 (DTU-15) | 0 | 1.63 | 6.74 |
Ocean Tide 1 (GOT4.10c) | 0 | 0.0 | 0.07 |
Ocean Tide 2 (FES2014b) | 0 | 0.0 | 0.08 |
Loading Tide 1 (GOT4.10c) | 0 | 0.0 | 0.004 |
Loading Tide 2 (FES2014b) | 0 | 0.0 | 0.005 |
Solid Earth Tide | 0 | –0.02 | 0.03 |
Pole Tide | 0 | 0.0 | 0.002 |
DTC (ECMWF) | 0 | –2.30 | 0.02 |
WTC (ECMWF) | 0 | –0.08 | 0.03 |
WTC (MWR) | 0 | –0.21 | 0.12 |
Iono (Dual Freq.) | 50.4 | 0.08 | 0.27 |
iono (GIM) | 0.6 | –0.02 | 0.002 |
Inv. Barometer | 0 | 0.0 | 0.10 |
High freq. DAC | 0 | 0.0 | 0.05 |
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Quartly, G.D.; Rinne, E.; Passaro, M.; Andersen, O.B.; Dinardo, S.; Fleury, S.; Guillot, A.; Hendricks, S.; Kurekin, A.A.; Müller, F.L.; et al. Retrieving Sea Level and Freeboard in the Arctic: A Review of Current Radar Altimetry Methodologies and Future Perspectives. Remote Sens. 2019, 11, 881. https://doi.org/10.3390/rs11070881
Quartly GD, Rinne E, Passaro M, Andersen OB, Dinardo S, Fleury S, Guillot A, Hendricks S, Kurekin AA, Müller FL, et al. Retrieving Sea Level and Freeboard in the Arctic: A Review of Current Radar Altimetry Methodologies and Future Perspectives. Remote Sensing. 2019; 11(7):881. https://doi.org/10.3390/rs11070881
Chicago/Turabian StyleQuartly, Graham D., Eero Rinne, Marcello Passaro, Ole B. Andersen, Salvatore Dinardo, Sara Fleury, Amandine Guillot, Stefan Hendricks, Andrey A. Kurekin, Felix L. Müller, and et al. 2019. "Retrieving Sea Level and Freeboard in the Arctic: A Review of Current Radar Altimetry Methodologies and Future Perspectives" Remote Sensing 11, no. 7: 881. https://doi.org/10.3390/rs11070881
APA StyleQuartly, G. D., Rinne, E., Passaro, M., Andersen, O. B., Dinardo, S., Fleury, S., Guillot, A., Hendricks, S., Kurekin, A. A., Müller, F. L., Ricker, R., Skourup, H., & Tsamados, M. (2019). Retrieving Sea Level and Freeboard in the Arctic: A Review of Current Radar Altimetry Methodologies and Future Perspectives. Remote Sensing, 11(7), 881. https://doi.org/10.3390/rs11070881