论文信息 - The Benefits of the Ka-Band as Evidenced from the SARAL/AltiKa Altimetric Mission: Scientific Applications - 字舞流文

The Benefits of the Ka-Band as Evidenced from the SARAL/AltiKa Altimetric Mission: Scientific Applications

The India–France SARAL/AltiKa mission is the first Ka-band altimetric mission dedicated primarily to oceanography. The mission objectives were firstly the observation of the oceanic mesoscales but also global and regional sea level monitoring, including the coastal zone, data assimilation, and operational oceanography. SARAL/AltiKa proved also to be a great opportunity for inland waters applications, for observing ice sheet or icebergs, as well as for geodetic investigations. The mission ended its nominal phase after three years in orbit and began a new phase (drifting orbit) in July 2016. The objective of this paper is to highlight some of the most remarkable achievements of the SARAL/AltiKa mission in terms of scientific applications. Compared to the standard Ku-band altimetry measurements, the Ka-band provides substantial improvements in terms of spatial resolution and data accuracy. We show here that this leads to remarkable advances in terms of observation of the mesoscale and coastal ocean, waves, river water levels, ice sheets, icebergs, fine scale bathymetry features as well as for the many related applications.

Raj Kumar | Jean-François Crétaux | Ananda Pascual | Jean Tournadre | Walter H. F. Smith | P. K. Gupta | Pascal Bonnefond | Jacques Verron | Lotfi Aouf | Florence Birol | Suchandra A. Bhowmick | Stéphane Calmant | Taina Conchy | Gerald Dibarboure | A. K. Dubey | Yannice Faugère | Kevin Guerreiro | Mathieu Hamon | Fatma Jebri | Rosemary Morrow | Marie-Isabelle Pujol | Elisabeth Rémy | Frédérique Rémy | Oscar Vergara | J. Crétaux | S. Calmant | J. Tournadre | F. Rémy | R. Morrow | L. Aouf | A. Pascual | M. Pujol | P. Bonnefond | F. Birol | O. Vergara | Raj Kumar | J. Verron | Y. Faugère | G. Dibarboure | E. Rémy | A. Dubey | S. A. Bhowmick | M. Hamon | Kevin Guerreiro | Fatma Jebri | P. K. Gupta | Taina Conchy

[1] Siyuan Wang,et al. Climate warming and growth of high-elevation inland lakes on the Tibetan Plateau , 2009 .

[2] David Griffin,et al. The SARAL/AltiKa Altimetry Satellite Mission , 2015 .

[3] Walter H. F. Smith. The Marine Geoid and Satellite Altimetry , 2010 .

[4] Jacques Verron,et al. Ice sheet survey over Antarctica using satellite altimetry: ERS-2, Envisat, SARAL/AltiKa, the key importance of continuous observations along the same repeat orbit , 2014 .

[5] W. Cudlip,et al. Observation of a giant Antarctic tabular iceberg by satellite radar altimetry , 1987, Polar Record.

[6] Fernando Niño,et al. Observability of fine-scale ocean dynamics in the northwestern Mediterranean Sea , 2016 .

[7] Jean Tournadre. Signature of Lighthouses, Ships, and Small Islands in Altimeter Waveforms , 2007 .

[8] Paul Poli,et al. Diagnosis of observation, background and analysis‐error statistics in observation space , 2005 .

[9] Rosemary Morrow,et al. Mesoscale resolution capability of altimetry: Present and future , 2016 .

[10] A. Cazenave,et al. Preliminary results of ENVISAT RA-2-derived water levels validation over the Amazon basin , 2006 .

[11] Yongwei Sheng,et al. Response of inland lake dynamics over the Tibetan Plateau to climate change , 2014, Climatic Change.

[12] Alexei V. Kouraev,et al. Study of Lake Baikal Ice Cover from Radar Altimetry and In–Situ Observations , 2015 .

[13] Paul Wessel,et al. Global distribution of seamounts inferred from gridded Geosat/ERS‐1 altimetry , 2001 .

[14] J. Tournadre,et al. Antarctic icebergs distributions 1992 – 2014 , 2016 .

[15] Jochen Horstmann,et al. HF Radar Activity in European Coastal Seas: Next Steps toward a Pan-European HF Radar Network , 2017, Front. Mar. Sci..

[16] Christian Schwatke,et al. Potential of SARAL/AltiKa for Inland Water Applications , 2015 .

[17] Frédérique Seyler,et al. Radar Altimetry Aids Managing Gauge Networks , 2014, Water Resources Management.

[18] Subashisa Dutta,et al. Water Level Retrieval Using SARAL/AltiKa Observations in the Braided Brahmaputra River, Eastern India , 2015 .

[19] Jean Tournadre,et al. Antarctic icebergs distributions 1992-2014: ANTARCTIC ICEBERG , 2016 .

[20] Bin Wang,et al. Tibetan Plateau warming and precipitation changes in East Asia , 2008 .

[21] H. Roquet,et al. Use of satellite observations for operational oceanography: recent achievements and future prospects , 2015 .

[22] Jean Tournadre,et al. Antarctic icebergs distributions, 2002–2010 , 2012 .

[23] Frédérique Seyler,et al. Stage‐discharge rating curves based on satellite altimetry and modeled discharge in the Amazon basin , 2016 .

[24] Joaquín Tintoré,et al. Computation of a new mean dynamic topography for the Mediterranean Sea from model outputs, altimeter measurements and oceanographic in situ data , 2014 .

[25] Denis Blumstein,et al. Envisat and SARAL/AltiKa Observations of the Antarctic Ice Sheet: A Comparison Between the Ku-band and Ka-band , 2015 .

[26] Frédéric Frappart,et al. Preliminary Assessment of SARAL/AltiKa Observations over the Ganges-Brahmaputra and Irrawaddy Rivers , 2015 .

[27] Yannice Faugère,et al. DUACS DT2014: the new multi-mission altimeter data set reprocessed over 20years , 2016 .

[28] Walter H. F. Smith. Resolution of Seamount Geoid Anomalies Achieved by the SARAL/AltiKa and Envisat RA2 Satellite Radar Altimeters , 2015 .

[29] J. Crétaux,et al. Lake studies from satellite radar altimetry , 2006 .

[30] Massimo Menenti,et al. Geometric dependency of Tibetan lakes on glacial runoff , 2013 .

[31] Frédérique Seyler,et al. Continental surface waters from satellite altimetry , 2006 .

[32] Walter H. F. Smith,et al. Detecting small seamounts in AltiKa repeat cycle data , 2016, Marine Geophysical Research.

[33] Michael T. Chandler,et al. The spatial and temporal distribution of marine geophysical surveys , 2011 .

[34] Joaquín Tintoré,et al. Assessing SARAL/AltiKa Data in the Coastal Zone: Comparisons with HF Radar Observations , 2015 .

[35] Jean-François Crétaux,et al. Use of SARAL/AltiKa over Mountainous Lakes, Intercomparison with Envisat Mission , 2015 .

[36] R. Sorgente,et al. Numerical simulation and decomposition of kinetic energy in the Central Mediterranean: insight on mesoscale circulation and energy conversion , 2011 .

[37] Bruno Zakardjian,et al. Exploiting coastal altimetry to improve the surface circulation scheme over the central Mediterranean Sea , 2016 .

[38] Gerald Dibarboure,et al. Gauging the Improvement of Recent Mean Sea Surface Models: A New Approach for Identifying and Quantifying Their Errors , 2018, Journal of Geophysical Research: Oceans.

[39] Pierre Prandi,et al. The Benefits of the Ka-Band as Evidenced from the SARAL/AltiKa Altimetric Mission: Quality Assessment and Unique Characteristics of AltiKa Data , 2018, Remote. Sens..

[40] Kevin Guerreiro,et al. Potential for estimation of snow depth on Arctic sea ice from CryoSat-2 and SARAL/AltiKa missions , 2016 .

[41] Jean Tournadre,et al. Large icebergs characteristics from altimeter waveforms analysis , 2015 .

[42] Gilles Larnicol,et al. Jason-2 in DUACS: Updated System Description, First Tandem Results and Impact on Processing and Products , 2011 .

[43] Laurent Rey,et al. AltiKa: a Ka-band Altimetry Payload and System for Operational Altimetry during the GMES Period , 2006, Sensors (Basel, Switzerland).

[44] J. Crétaux,et al. Lake Volume Monitoring from Space , 2016, Surveys in Geophysics.

[45] F. O'Loughlin,et al. Opportunities for hydrologic research in the Congo Basin , 2016 .

[46] S. Calmant,et al. Water levels in the Amazon basin derived from the ERS 2 and ENVISAT radar altimetry missions , 2010 .

[47] Frédérique Seyler,et al. Global determination of rating curves in the Amazon basin from satellite altimetry , 2014 .