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Publications about 'California'

Articles in journal or book chapters

  1. Ekaterina Tymofyeyeva and Yuri Fialko. Mitigation of atmospheric phase delays in InSAR data, with application to the eastern California shear zone. Journal of Geophysical Research: Solid Earth, 120(8):5952-5963, 2015. Note: 2015JB011886. Keyword(s): SAR Processing, Interferometry, SAR interferometry, differential SAR interferometry, DInSAR, Displacement, Surface Displacement, Atmosphere, APS, Transient deformation, Satellite geodesy: results, Satellite geodesy: technical issues, Seismic cycle related deformations, Integrations of techniques, InSAR, time series, atmospheric delays, transient deformation. [Abstract] [bibtex-entry]


  2. Z. W. Li, W. B. Xu, G. C. Feng, J. Hu, C. C. Wang, X. L. Ding, and J. J. Zhu. Correcting atmospheric effects on InSAR with MERIS water vapour data and elevation-dependent interpolation model. Geophysical Journal International, 189(2):898-910, 2012. Keyword(s): SAR Processing, Interferometry, SAR interferometry, differential SAR interferometry, DInSAR, Displacement, Surface Displacement, Atmosphere, APS, MERIS, MERIS water vapour data, water vapour, Image processing, Satellite geodesy, Radar interferometry, Creep and deformation, Wave propagation. [Abstract] [bibtex-entry]


  3. Meng Wei and David T. Sandwell. Decorrelation of L-Band and C-Band Interferometry Over Vegetated Areas in California. IEEE Trans. Geosci. Remote Sens., 48(7):2942-2952, July 2010. Keyword(s): SAR Processing, Decorrelation, Temporal Decorrelation, Earth crust, faulting, geomorphology, radar interferometry, remote sensing by radar, synthetic aperture radar, vegetation mapping, C-band European Remote Sensing Satellite interferograms, Coast Range area, ERS interferogram, Imperial Valley, L-band Advanced Land Observation Satellite interferograms, Northern California forests, Parkfleld, San Andreas Fault system, Southern California, crustal deformation, decorrelation behavior, decorrelation time, fault creep, interferometric synthetic aperture radar, interseismic deformation, local uplifting signal, near-fault interseismic deformation, sandy surfaces, seasonal acquisitions, signal-to-noise ratio, spatial baseline, spatial baseline lost correlation, temporal baseline, temporal baseline lost correlation, vegetated areas, Correlation, crustal deformation, interferometry, synthetic aperture radar (SAR). [Abstract] [bibtex-entry]


  4. Riccardo Lanari, Francesco Casu, Mariarosaria Manzo, and Paul Lundgren. Application of the SBAS-DInSAR technique to fault creep: A case study of the Hayward fault, California. Remote Sensing of Environment, 109(1):20-28, 2007. [bibtex-entry]


  5. Riccardo Lanari, Francesco Casu, Mariarosaria Manzo, Giovanni Zeni, Paolo Berardino, Michele Manunta, and Antonio Pepe. An Overview of the Small BAseline Subset Algorithm: a DInSAR Technique for Surface Deformation Analysis. Pure and Applied Geophysics, 164(4):637-661, April 2007. [Abstract] [bibtex-entry]


  6. C. Colesanti, A. Ferretti, F. Novali, C. Prati, and F. Rocca. SAR monitoring of progressive and seasonal ground deformation using the permanent scatterers technique. IEEE Trans. Geosci. Remote Sens., 41(7):1685-1701, July 2003. Keyword(s): SAR Processing, Persistent Scatterer Interferometry, PSI, California, Fremont, SAR, San Jose, Santa Clara Valley, Southern Bay Area, USA, United States, coseismic displacement, differential radar interferometry, geodesy, geodetic deformation, geophysical measurement technique, land surface, permanent scatterer, phase decorrelation, postseismic displacement, progressive deformation, radar remote sensing, seasonal ground deformation, spaceborne radar, subsidence, synthetic aperture radar, terrain mapping, geodesy, geophysical techniques, radar theory, remote sensing by radar, spaceborne radar, synthetic aperture radar, terrain mapping;. [Abstract] [bibtex-entry]


  7. David A. Schmidt and Roland Bürgmann. Time-dependent land uplift and subsidence in the Santa Clara valley, California, from a large interferometric synthetic aperture radar data set. J. Geophys. Res., 108(B9):2416, September 2003. Keyword(s): SAR Processing, PSI, Persistent Scatterer Interferometry, Interferometry, SAR Interferometry, InSAR, Differential SAR Interferometry, DInSAR, Groundwater hydrology, Water supply, Physical Properties of Rocks, Permeability and porosity, Space geodetic surveys. [Abstract] [bibtex-entry]


  8. Simon Williams, Yehuda Bock, and Peng Fang. Integrated satellite interferometry: Tropospheric noise, GPS estimates and implications for interferometric synthetic aperture radar products. Journal of Geophysical Research: Solid Earth, 103(B11):27051-27067, 1998. Keyword(s): SAR Processing, Interferometry, SAR interferometry, differential SAR interferometry, DInSAR, Displacement, Surface Displacement, Atmosphere, APS, Geodesy and Gravity, Instruments and techniques, Interferometry, GPS, GNSS. [Abstract] [bibtex-entry]


  9. Richard M. Goldstein. Atmospheric limitations to repeat-track radar interferometry. Geophysical Research Letters, 22(18):2517-2520, 1995. Keyword(s): SAR Processing, SAR Processing, Interferometry, SAR interferometry, Atmospheric Composition and Structure: Troposphere-composition and chemistry, Geodesy and Gravity: Space geodetic surveys, Geodesy and Gravity: Instruments and techniques, Radio Science: Remote sensing. [Abstract] [bibtex-entry]


  10. Didier Massonnet, Kurt Feigl, Marc Rossi, and Frederic Adragna. Radar interferometric mapping of deformation in the year after the Landers earthquake. Nature, 369(6477):227-230, May 1994. Keyword(s): SAR Processing, Interferometry, SAR interferometry, differential SAR interferometry, DInSAR, Deformation Mapping, Deformation Monitoring, ERS-1, Displacement, Surface Displacement, Surface Deformation, Spaceborne SAR, C-band, Earthquake, Landers earthquake, Fault Slip. [Abstract] [bibtex-entry]


  11. Howard A. Zebker, Paul A. Rosen, Richard M. Goldstein, Andrew Gabriel, and Charles L. Werner. On the derivation of coseismic displacement fields using differential radar interferometry: The Landers earthquake. Journal of Geophysical Research: Solid Earth, 99(B10):19617-19634, 1994. Keyword(s): SAR Processing, Interferometry, SAR interferometry, differential SAR interferometry, DInSAR, Deformation Mapping, Deformation Monitoring, ERS-1, Displacement, Surface Displacement, Surface Deformation, Spaceborne SAR, C-band, Earthquake, Landers earthquake, Fault Slip, Remote sensing, Seismic instruments and networks, Earthquake source observations, Earthquake interaction, forecasting, and prediction. [Abstract] [bibtex-entry]


  12. Didier Massonnet, Marc Rossi, Cesar Carmona, Frederic Adragna, Gilles Peltzer, Kurt Feigl, and Thierry Rabaute. The displacement field of the Landers earthquake mapped by radar interferometry. Nature, 364(6433):138-142, July 1993. Keyword(s): SAR Processing, Interferometry, SAR interferometry, differential SAR interferometry, DInSAR, Deformation Mapping, Deformation Monitoring, ERS-1, Displacement, Surface Displacement, Surface Deformation, Spaceborne SAR, C-band, Earthquake, Landers earthquake, Fault Slip. [Abstract] [bibtex-entry]


  13. Andrew K. Gabriel, Richard M. Goldstein, and Howard A. Zebker. Mapping small elevation changes over large areas: Differential radar interferometry. Journal of Geophysical Research: Solid Earth, 94(B7):9183-9191, 1989. Keyword(s): Review Paper, SAR Processing, Interferometry, SAR Interferometry, differential SAR Interferometry, DInSAR, InSAR, deformation mapping, surface deformation, surface displacement, Topographic Mapping, Planetology: Solid Surface Planets and Satellites: Surfaces, Remote sensing, Radar astronomy. [Abstract] [bibtex-entry]


  14. Jakob van Zyl. Unsupervised classification of scattering behavior using radar polarimetry data. IEEE Trans. Geosci. Remote Sens., 27(1):36-45, January 1989. Keyword(s): imaging radar polarimeter, land surface measurement, ocean, radar polarimetry, remote sensing technique, scattering behavior, unsupervised classification, urban, vegetation, electromagnetic wave polarisation, electromagnetic wave scattering, geophysical techniques, oceanographic techniques, radar applications, remote sensing;. [Abstract] [bibtex-entry]


Conference articles

  1. Leif J. Harcke. Time-domain backprojection for precise geodetic coding of spaceborne SAR imagery. In Radar Conference, 2009 IEEE, pages 1-3, May 2009. Keyword(s): SAR Processing, TDBP, Time-Domain Back-Projection, ALOS/PALSAR instrument, D-InSAR, WGS-84 Cartesian system, backprojection image formation, differential radar interferometry, geocoded image production, geodetic coding, position measurement, precise-orbit determination, reflector, space-borne SAR, spaceborne SAR imagery, time-domain back-projection, geodesy, position measurement, radar imaging, radar interferometry, spaceborne radar, synthetic aperture radar. [Abstract] [bibtex-entry]


  2. P.A. Rosen, S. Hensley, and C. Le. Observations and mitigation of RFI in ALOS PALSAR SAR data: Implications for the DESDynI mission. In IEEE Radar Conference, pages 1-6, May 2008. Keyword(s): DESDynI mission, L-band polarimetric radar, RFI, SAR data, radio frequency interference, synthetic aperture radar, radiofrequency interference, synthetic aperture radar. [Abstract] [bibtex-entry]


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Please note that access to full text PDF versions of papers is restricted to the Chair of Earth Observation and Remote Sensing, Institute of Environmental Engineering, ETH Zurich.
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This collection of SAR literature is far from being complete.
It is rather a collection of papers which I store in my literature data base. Hence, the list of publications under PUBLICATIONS OF AUTHOR'S NAME should NOT be mistaken for a complete bibliography of that author.




Last modified: Mon Feb 1 16:39:22 2021
Author: Othmar Frey, Earth Observation and Remote Sensing, Institute of Environmental Engineering, Swiss Federal Institute of Technology - ETH Zurich .


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