Publications about 'differential radar interferometry'

Articles in journal or book chapters

  1. Simone Baffelli, Othmar Frey, and Irena Hajnsek. Geostatistical Analysis and Mitigation of the Atmospheric Phase Screens in Ku-Band Terrestrial Radar Interferometric Observations of an Alpine Glacier. IEEE Transactions on Geoscience and Remote Sensing, 58(11):7533-7556, November 2020. Keyword(s): Gamma Portable Radar Interferometer, GPRI, Pol-GPRI, Atmospheric modeling, Spaceborne radar, Atmospheric measurements, Radar interferometry, Delays, Phase measurement, Atmospheric modeling, atmospheric phase screen (APS), differential radar interferometry, terrestrial radar interferometry, TRI. [Abstract] [bibtex-entry]

  2. Silvan Leinss, Andreas Wiesmann, J. Lemmetyinen, and I. Hajnsek. Snow Water Equivalent of Dry Snow Measured by Differential Interferometry. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, 8(8):3773-3790, August 2015. Keyword(s): radar interferometry, remote sensing by radar, snow, Finland, SnowScat instrument, Sodankyla town, Xand Ku-band, active microwave remote sensing method, differential interferogram time series, differential radar interferometry, dry snow measurement, frequency 10 GHz, frequency 16 GHz, frequency 20 GHz, passive microwave remote sensing method, phase wrapping error, reference instrument, signal delay, snow density, snow pack spatial inhomogeneity, snow volume, snow water equivalent mapping, stratigraphy, temporal decorrelation, time 30 day, Backscatter, Ice, Instruments, Interferometry, Snow, Synthetic aperture radar, Coherence loss, SnowScat, dielectric constant of snow, differential interferometry (D-InSAR), dry snow, microwave penetration of snow, real aperture radar, snow water equivalent (SWE), synthetic aperture radar (SAR). [Abstract] [bibtex-entry]

  3. 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]

  4. 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]

  5. 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]

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]



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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 16:39:35 2021
Author: Othmar Frey, Earth Observation and Remote Sensing, Institute of Environmental Engineering, Swiss Federal Institute of Technology - ETH Zurich .

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