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44 results on '"Fornaro, A"'

2. Joint Phase-Screen Estimation in Airborne Multibaseline SAR Tomography Data Processing

Author

Imperatore, Pasquale and Fornaro, Gianfranco

Abstract

Airborne interferometric data is typically affected by phase distortions originated from subwavelength residual positioning uncertainties (phase screen) when acquired along different tracks. Available methods estimate the phase screen affecting stacks of multibaseline acquisitions, mainly by exploiting single interfograms separately. A novel method for the joint estimation of the multibaseline phase screens is proposed. The results of the implemented phase calibration are analyzed via a tomographic inversion, allowing to obtain a 3-D imaging estimating the vertical characteristics of the scene scattering. Specifically, we processed the multibaseline, fully polarized P-band synthetic aperture radar (SAR) data collected during the AfriSAR campaign in July 2015 over the Lopé tropical forests in Gabon, West Africa. Validation of the 3-D imaging results, supported by reference LiDAR (NASA LVIS) data, allowed demonstrating that the proposed joint estimation method overcomes the classical disjoint estimation solutions.

Published
2024
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3. Potentials and limitations of Moon-Borne SAR imaging

Author

Fornaro, G., Franceschetti, G., Lombardini, F., Mori, A., and Calamia, M.

Subjects
Interferometry -- Usage, Lunar photography -- Evaluation, Satellite imaging -- Evaluation, Synthetic aperture radar -- Design and construction, Business, Earth sciences, Electronics and electrical industries
Published
2010

4. Detection of single scatterers in multidimensional SAR imaging

Author

De Maio, Antonio, Fornaro, Gianfranco, and Pauciullo, Antonio

Subjects
Synthetic aperture radar -- Usage, Artificial satellites in remote sensing -- Methods, Tomography -- Methods, Imaging systems -- Methods, Business, Earth sciences, Electronics and electrical industries
Abstract

Multidimensional synthetic aperture radar (SAR) imaging is a technique based on coherent SAR data combination for space (full 3-D) and space deformation--velocity (4-D) analysis. It is an extension of the concepts of SAR interferometry and differential interferometry SAR and offers new options for the analysis and monitoring of ground scenes. In this paper, we consider the problem of detecting single scatterers for localization and monitoring issues. To this end, we resort to a constant false alarm rate (CFAR) detection scheme which can be synthesized according to three different design criteria: generalized likelihood ratio test, Rao test, and Wald test. At the analysis stage, the performance of the aforementioned detector is compared to that of a previously proposed CFAR scheme, based on the multi-interferogram complex coherence and widely used in persistent scatterer interferometry. The analysis is conducted both on simulated and on real SAR data, acquired by ERS-1/2 satellites. Finally, Cramer--Rao lower bounds for the estimation of the scatterer elevation and velocity are provided. Index Terms--Differential tomography, multidimensional synthetic aperture radar (SAR) imaging, scatterer detection.

Published
2009

5. Four-dimensional SAR imaging for height estimation and monitoring of single and double scatterers

Author

Fornaro, Gianfranco, Reale, Diego, and Serafino, Francesco

Subjects
Synthetic aperture radar -- Analysis, Tomography -- Analysis, Business, Earth sciences, Electronics and electrical industries
Abstract

The superposition of contributions from different stable targets within the same pixel is a phenomenon that may impair the imaging and monitoring of ground scatterers via the multipass synthetic aperture radar (SAR) interferometry technique. Three-dimensional SAR imaging, also known as SAR tomography, uses multiple views to profile the scattering power at different heights. This technique has been shown to be capable of separating interfering target responses on real data. Differential SAR tomography has been recently proposed as a technique that extends the potentialities of SAR tomography to the target deformation monitoring. It performs a 4-D space--velocity imaging that enables not only separating interfering targets in elevation but also distinguishing their single slow deformation velocities. This work addresses for the first time the application of 4-D SAR imaging to real data to determine the height and mean deformation velocity of single scatterers and double-scattering mechanisms interfering at high resolution in the same pixel. It also discusses the postprocessing steps required to identify the presence of stable single and double scatterers after elevation--velocity focusing. Moreover, it proposes a technique for the extraction of time series from interfering targets to measure possible nonlinear temporal deformations. Index Terms--Differential synthetic aperture radar (SAR) tomography, multibaseline/multitemporal coherent SAR processing, permanent scatterers interferometry, 4-D SAR imaging.

Published
2009

6. LMMSE 3-D SAR focusing

Author

Fornaro, Gianfranco and Pauciullo, Antonio

Subjects
Synthetic aperture radar -- Analysis, Tomography -- Analysis, Business, Earth sciences, Electronics and electrical industries
Abstract

Three-dimensional synthetic aperture radar (SAR) imaging, a technique also known as SAR tomography, uses multiple views to extend the capability of SAR systems to 3-D imaging by achieving a profiling of the scattering power at different heights. Multiple views are obtained with the current satellite technology via successive passes of a single antenna SAR sensor over the same scene, but next-generation sensor formations are foreseen to acquire multistatic data. Conventional processing, such as the beamforming, or singular values decomposition inversion is based on geometrical derivations and, hence, assumes the accurate phase calibration and the absence of target decorrelation. This paper analyzes the effects of phase miscalibration due to residual uncompensated atmospheric contribution and temporal decorrelation and proposes a 3-D imaging technique based on a linear minimum mean square error approach. The resulting algorithm extends the possibilities of the conventional processing by carrying out an integration of data that accounts for the a priori data correlation properties. Hence, it allows handling of the presence of additional stochastic contributions such as: temporal coherence losses and atmospheric phase miscalibration. Moreover, with reference to future bistatic and multistatic systems, it permits an improved coherent integration of data acquired by simultaneous antenna in repeated passes. Index Terms--3-D SAR tomography, 3-D synthetic aperture radar (3-D SAR) imaging.

Published
2009

7. X-band airborne differential interferometry: results of the OrbiSAR campaign over the perugia area

Author

Perna, Stefano, Wimmer, Christian, Moreira, Joao, and Fornaro, Gianfranco

Subjects
Remote sensing -- Research, Interferometry -- Methods, Synthetic aperture radar -- Usage, Business, Earth sciences, Electronics and electrical industries
Abstract

Differential synthetic aperture radar interferometry (DInSAR) is a remote sensing technique that allows monitoring ground deformation with accuracy of the order of fractions of the radiated wavelength, by means of proper combination and processing of repeat-pass data. In contrast to the satellite case, application of such a technique to airborne data is not, today, a well-established task. Several airborne campaigns, involving mainly C/L-band data, have been planned in the last years to exploit the potentialities of these more flexible platforms for deformation monitoring. In this paper, we show the results of an airborne DInSAR X-band experiment carried out over the Perugia area (center of Italy) by using the OrbiSAR system. We discuss the processing chain applied to the acquired data, which allows achieving a satisfactory compromise between accuracy and efficiency. Eleven repeated passes were carried out in two days; two corner reflectors were located on the ground in a hilly region. One corner reflector was vertically moved between the two days to evaluate the system detection capability. Moreover, we carry out an analysis of all possible differential interferograms for a region 2 x 4 km wide. Index Terms--Airborne differential SAR interferometry, airborne repeat pass SAR interferometry, synthetic aperture radar (SAR).

Published
2008

8. Phase Calibration Based on Phase Derivative Constrained Optimization in Multibaseline SAR Tomography

Author

Gilda Schirinzi, Gianfranco Fornaro, and Hossein Aghababaee

Subjects
Synthetic aperture radar, Phase derivative, Computer science, Scattering, 0211 other engineering and technologies, Constrained optimization, volumetric media, Terrain, 02 engineering and technology, synthetic aperture radar (SAR), tomography, Phase calibration, 0202 electrical engineering, electronic engineering, information engineering, General Earth and Planetary Sciences, Entropy (information theory), 020201 artificial intelligence & image processing, Tomography, Electrical and Electronic Engineering, Earth and Planetary Sciences (all), Algorithm, 021101 geological & geomatics engineering
Abstract

This paper deals with the compensation of phase miscalibration in the general context of tomographic synthetic aperture radar image focusing. Phase errors are typically independent of one acquisition to the other, thus leading to a spreading and defocusing in the multidimensional (3-D, 4-D, and 5-D) imaging space. Coping with this problem in presence of volumetric scattering is generally a complex issue. In this paper, we consider the approach for phase calibration characterized by the advantage, with respect to classical phase calibration algorithms, of not requiring either the identification of a reference target or specific assumptions about the unknown phase function, or a priori information about the terrain topography. The novelty of the proposed phase miscalibration estimation and compensation method is related to its ability to avoid unwanted and uncontrollable vertical shifts in the focused image. The estimation of the calibration phase is performed by optimizing the contrast or the entropy of the vertical profile with the constraint of a zero phase derivative. Such a constraint preserves the output height distribution. Experimental results of simulated and real data are included to demonstrate the effectiveness of the proposed method.

Published
2018
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9. Imaging of single and double scatterers in urban areas via SAR tomography

Author

Fornaro, Gianfranco and Serafino, Francesco

Subjects
Metropolitan areas -- Environmental aspects, Tomography -- Usage, Remote sensing -- Usage, Synthetic aperture radar -- Usage, Business, Earth sciences, Electronics and electrical industries
Abstract

Microwave scattering is a rather complex mechanism, especially in urban areas. Three-dimensional (3-D) synthetic aperture radar (SAR) tomography is a technique that uses multiple views to map the scattering power at different heights, thus extending the capability of SAR sensors to fully image the scene in the 3-D space. This paper presents a first validation of spaceborne long-term SAR tomography by demonstrating the capability to resolve a simple layover case, i.e., to separate single- and double-scattering mechanisms within imaged pixels. Results obtained with real data acquired by the European Remote Sensing 1 and 2 (ERS-1 and ERS-2) satellites over the urban area of Napoli are presented. As an additional contribution, an innovative algorithm estimating residual topography and surface deformation, called the spatial-differencing technique, is also discussed in detail at the data calibration stage. Index Terms--Multibaseline coherent synthetic aperture radar (SAR) processing, SAR tomography, three-dimensional (3-D) SAR focusing.

Published
2006

10. Geometrical SAR image registration

Author

Sansosti, Eugenio, Berardino, Paolo, Manunta, Michele, Serafino, Francesco, and Fornaro, Gianfranco

Subjects
Algorithms -- Technology application, Algorithms -- Research, Remote sensing -- Research, Synthetic aperture radar -- Research, Algorithm, Technology application, Business, Earth sciences, Electronics and electrical industries
Abstract

Accurate subpixel registration of synthetic aperture radar (SAR) images is an issue that is again growing interest since its initial developments related to two-pass interferometry. Recent progress in coherent (multichannel) SAR processing raises the need for accurate registration of data takes acquired with large baseline spans, high temporal coverage, and with different frequency and/or operational modes. In this paper, we discuss a SAR image-registration procedure, based on the use of external measures which allows obtaining a very accurate alignment of SAR images. The presented technique makes use of a digital elevation model and of the precise information about the acquisition flight tracks, to compute the warping functions that map the position of each pixel in the different takes, thus avoiding any approximation. The resulting algorithm is simple, robust, precise, and very efficient; as a matter of fact, it may achieve high accuracy even in critical areas, such as steep topography regions. Moreover, the availability of an analytical and exact model allows performing a detailed sensitivity analysis that can be useful in evaluating the applicability of this technique even to future high-precision satellite systems. Extensive testing, carried out on several real European Remote Sensing and ENVISAT datasets, clearly shows the effectiveness of such algorithm in registering critical SAR images. Index Terms--Image registration, multichannel SAR, synthetic aperture radar (SAR) interferometry (InSAR).

Published
2006

12. Three-dimensional multipass SAR focusing: experiments with long-term spaceborne data

Author

Fornaro, Gianfranco, Lombardini, Fabrizio, and Serafino, Francesco

Subjects
Tomography -- Research, Remote sensing -- Research, Synthetic aperture radar -- Research, Business, Earth sciences, Electronics and electrical industries
Abstract

Synthetic aperture radar (SAR) interferometry is a modern efficient technique that allows reconstructing the height profile of the observed scene. However, apart for the presence of critical nonlinear inversion steps, particularly crucial in abrupt topography scenarios, it does not allow one to separate different scattering mechanisms in the elevation (height) direction within the ground pixel. Overlay of scattering at different elevations in the same azimuth-range resolution cell can be due either to the penetration of the radiation below the surface or to perspective ambiguities caused by the side-looking geometry. Multibaseline three-dimensional (3-D) SAR focusing allows overcoming such a limitation and has thus raised great interest in the recent research. First results with real data have been only obtained in the laboratory and with airborne systems, or with limited time-span and spatial-coverage spaceborne data. This work presents a novel approach for the tomographic processing of European Remote Sensing satellite (ERS) real data for extended scenes and long time span. Besides facing problems common to the airborne case, such as the nonuniformly spaced passes, this processing requires tackling additional difficulties specific to the spaceborne case, in particular a space-varying phase calibration of the data due to atmospheric variations and possible scene deformations occurring for years-long temporal spans. First results are presented that confirm the capability of ERS multipass tomography to resolve multiple targets within the same azimuth-range cell and to map the 3-D scattering properties of the illuminated scene. Index Terms--Multibaseline, multipass, synthetic aperture radar (SAR), three-dimensional (3-D) focusing, tomography.

Published
2005

13. Three-dimensional focusing with multipass SAR data

Author

Fornaro, Gianfranco, Serafino, Francesco, and Soldovieri, Francesco

Subjects
Synthetic aperture radar -- Usage, Tomography -- Equipment and supplies, Scattering (Physics) -- Measurement, Business, Earth sciences, Electronics and electrical industries
Abstract

This paper deals with the use of multipass synthetic aperture radar (SAR) data in order to achieve three-dimensional tomography reconstruction in presence of volumetric scattering. Starting from azimuth- and range-focused SAR data relative to the same area, neglecting any mutual interaction between the targets, and assuming the propagation in homogeneous media, we investigate the possibility to focus the data also in the elevation direction. The problem is formulated in the framework of linear inverse problem and the solution makes use of the singular value decomposition of the relevant operator. This allows us to properly take into account nonuniform orbit separation and to exploit a priori knowledge regarding the size of the volume interested by the scattering mechanism, thus leading to superresolution in the elevation direction. Results obtained on simulated data demonstrate the feasibility of the proposed processing technique. Index Terms--Synthetic aperture radar (SAR), three-dimensional focusing, tomography.

Published
2003

14. A new algorithm for surface deformation monitoring based on small baseline differential SAR interferograms

Author

Berardino, Paolo, Fornaro, Gianfranco, Lanari, Riccardo, and Sansosti, Eugenio

Subjects
Interferometry -- Technology application, Synthetic aperture radar -- Technology application, Deformations (Mechanics) -- Measurement, Technology application, Business, Earth sciences, Electronics and electrical industries
Abstract

We present a new differential synthetic aperture radar (SAR) interferometry algorithm for monitoring the temporal evolution of surface deformations. The presented technique is based on an appropriate combination of differential interferograms produced by data pairs characterized by a small orbital separation (baseline) in order to limit the spatial decorrelation phenomena. The application of the singular value decomposition method allows us to easily 'link' independent SAR acquisition datasets, separated by large baselines, thus increasing the observation temporal sampling rate. The availability of both spatial and temporal information in the processed data is used to identify and filter out atmospheric phase artifacts. We present results obtained on the data acquired from 1992 to 2000 by the European Remote Sensing satellites and relative to the Campi Flegrei caldera and to the city of Naples, Italy that demonstrate the capability of the proposed approach to follow the dynamics of the detected deformations. Index Terms--Ground deformations, SAR interferometry, synthetic aperture radar (SAR).

Published
2002

15. Minimum mean square error space-varying filtering of interferometric SAR data

Author

Fornaro, Gianfranco and Guarnieri, Andrea Monti

Subjects
Synthetic aperture radar -- Analysis, Interferometry -- Usage, Remote sensing -- Analysis, Business, Earth sciences, Electronics and electrical industries
Abstract

This paper addresses the problem of filtering interferometric synthetic aperture radar (IFSAR) signals in presence of nonplanar topography to mitigate geometrical decorrelation effects. The problem is space-variant. We assume knowledge about the scene topography and derive an optimal, minimum mean square error (MMSE), filtering procedure. The algorithm is flexible and, beside the standard stripmap-stripmap interferometry, it may be applied to IFSAR data acquired in any operative mode. For instance, in scan-scan, scan-strip, and scan-spot interferometry. The scene topography contribution may be either derived from an external rough digital elevation model (DEM) or directly estimated from the SAR data. The filtering technique is extended to the azimuth direction to account for possible Doppler centroid decorrelation. Experimental results carried out on real data confirm the validity of the theory and show that this filtering procedure allows us to obtain a reduction of the interferometric noise content. Its gain is particularly marked in the cases of steep topography, where application of the standard common band filters could deteriorate the signal quality, or for large Doppler centroid shifts between the two acquisitions. Index Terms--Minimum mean square error (MMSE) interferometric filtering, SAR interferometry (IFSAR), synthetic aperture radar (SAR).

Published
2002

16. A Two-Dimensional Region Growing Least Squares Phase Unwrapping Algorithm for Interferometric SAR Processing

Author

Fornaro, Gianfranco and Sansosti, Eugenio

Subjects
Synthetic aperture radar -- Information management, Least squares -- Usage, Interferometry -- Research, Business, Earth sciences, Electronics and electrical industries
Abstract

This paper presents a new two-dimensional (2-D) phase unwrapping (PhU) algorithm based on a least squares (LS) region growing strategy: the wrapped phase image is partitioned in different regions that are sequentially unwrapped via a LS algorithm. Reliable regions are dealt with at the beginning of the procedure, while critical areas are unwrapped in the final steps, thus avoiding error propagation from critical to reliable areas. A conditioned least squares formulation of the phase unwrapping problem is the core of the proposed procedure: this allows the solution to be tied to 'some' known boundary phase values, thus guaranteeing the correct joining of the reconstructed phase in between the different regions and preventing them from being independently unwrapped. The application of the finite element method allows a straightforward implementation of the algorithm in the discrete domain case. Experimental results, carried out on simulated and real interferometric SAR data, show the effectiveness of the proposed algorithm and the improved performances with respect to existing unwrapping procedures.

Published
1999

17. A short discussion on the exact compensation of the SAR range-dependent range cell migration effect

Author

Lanari, Riccardo and Fornaro, Gianfranco

Subjects
Synthetic aperture radar -- Usage, Scaling laws (Statistical physics) -- Analysis, Algorithms -- Usage, Business, Earth sciences, Electronics and electrical industries
Abstract

Efficient and precise compensation of the range cell migration (RCM) effect is a key point for a fast and accurate Synthetic Aperture Radar (SAR) data processor. In particular the range-dependent nature of the range cell migration effect complicates the compensation operation. It has been recently shown that an exact compensation of the range-dependent RCM (RDRCM) phenomenon can be carried out either by applying the chirp scaling algorithm or the chirp z-transform procedure. This paper investigates the relationship between the two methods. In particular, it is shown that the chirp z-transform based approach represents a particular implementation of the chirp scaling algorithm. A final discussion is dedicated to show how the chirp z-transform and the chirp scaling procedure can be applied within a SAR data processing algorithm. Index Terms - Synthetic aperture radar processing.

Published
1997

18. Synthetic aperture radar interferometry using one bit coded raw and reference signals

Author

Fornaro, Gianfranco, Pascazio, Vito, and Schirinzi, Gilda

Subjects
Interferometry -- Research, Synthetic aperture radar -- Usage, Remote sensing -- Methods, Business, Earth sciences, Electronics and electrical industries
Abstract

This paper is concerned about the generation of interferometric phase patterns using Synthetic Aperture Radar (SAR) images obtained by processing raw data and reference function both quanfized at one bit (Signum Coded). Such processing technique involves one-bit coded (i.e., binary) sequences, and can be efficiently implemented in real time using very simple and low cost hardware. It is shown that the proposed SC processing technique preserves, besides the image intensities, also interferometric phase patterns, before and after phase unwrapping. To test the performance of the proposed technique, experiments have been carried out on real data relative to the ERS-1 mission. Quantitative comparison between the results of conventional and SC processing clearly show that the presented method can be used for quick-look DEM's generation. Moreover, in accordance with the SC-SAR theory, an upsampling has also been performed on the signals to be processed to obtain higher quality patterns. This produce a noticeable improvement of the obtained results, so that the SC techniques can be considered a valid alternative to the conventional ones, still preserving the advantages in terms of real time. Index Terms - Synthetic aperture radar (SAR), SAR interferometry, SC-SAR.

Published
1997

19. Generation of digital elevation models by using SIR-C/X-SAR multifrequency two-pass interferometry: the Etna case study

Author

Lanari, Riccardo, Fornaro, Gianfranco, Riccio, Daniele, Migliaccio, Maurizio, Papathanassiou, Konstantinos P., Moreira, Joao R., Schwabisch, Marcus, Dutra, Luciano, Puglisi, Giuseppe, Franceschetti, Giorgio, and Coltelli, Mauro

Subjects
Synthetic aperture radar -- Usage, Interferometry -- Research, Earth sciences -- Remote sensing, Business, Earth sciences, Electronics and electrical industries
Abstract

In this paper, we exploit the interferometric multifrequency potentiality of the SIR-C/X-SAR system which is equipped with an L-, C-, and X-band sensor. We present a solution to improve the unwrapping performance of the C- and X-band data by considering the L-band unwrapped pattern. A new algorithm for the generation of a single digital elevation model (DEM) combining L-, C-, and X-band information is presented. This solution is based on the fusion of the unwrapped phase patterns by using a Kalman filter. The proposed fusion operation also accounts for the coherence characteristics of the three data sets. The selected test site is the Mt. Etna region in Italy which is very interesting from the volcanological and geological point of view. Numerical assessments of the achieved results are provided by evaluating the height accuracy with respect to a reference DEM.

Published
1996

20. Interferometric SAR phase unwrapping using Green's formulation

Author

Fornaro, G., Franceschetti, G., and Lanari, R.

Subjects
Potential theory (Mathematics) -- Usage, Interferometry -- Research, Synthetic aperture radar -- Research, Business, Earth sciences, Electronics and electrical industries
Abstract

Any method that permits retrieving full range (unwrapped) phase values starting from their (-[Pi], [Pi]) determination (wrapped phase) can be defined as a phase unwrapping technique. This paper addresses a new procedure for phase unwrapping especially designed for Interferometric synthetic aperture radar applications. The proposed algorithm is based on use of Green's first identity. Results on simulated as well as on real data are presented. They both confirm the excellent performance of the procedure.

Published
1996

21. Multi-Look in GLRT-Based Detection of Single and Double Persistent Scatterers

Author

Antonio Pauciullo, Walter Franze, Gianfranco Fornaro, and Diego Reale

Subjects
Synthetic aperture radar, Computer science, Detector, 0211 other engineering and technologies, Point cloud, 020206 networking & telecommunications, 02 engineering and technology, Interferometry, 0202 electrical engineering, electronic engineering, information engineering, General Earth and Planetary Sciences, Tomography, Electrical and Electronic Engineering, Image resolution, Algorithm, 021101 geological & geomatics engineering, Coherence (physics)
Abstract

Persistent scatterer (PS) interferometry and more recently synthetic aperture radar tomography have shown to be powerful tools in urban scenarios for providing 3-D point clouds in the reconstruction of buildings as well as in the monitoring of their possible slow temporal deformations. The detection of PSs represents a fundamental aspect, which in the literature has been mainly addressed at full resolution (single-look detection), thus considering only the scatterer coherence properties along the different acquisitions. In this paper, we investigate the benefits offered by the usage of multiple observation looks. Multi-look generalized likelihood ratio test detection schemes are derived and analyzed in terms of detection performances. The analysis shows that even a slight multi-look can provide a dramatic improvement on the detection capability both on simulated and real data, especially in the areas characterized by a low signal-to-noise ratio and in the presence of a limited number of acquisitions.

Published
2018
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24. Potentials and Limitations of Moon-Borne SAR Imaging

Author

Mario Calamia, Gianfranco Fornaro, Giorgio Franceschetti, Fabrizio Lombardini, and Alessandro Mori

Subjects
Synthetic aperture radar, Earth's orbit, Earth observation, Computer science, Natural Earth, synthetic aperture radar (SAR), Space exploration, Physics::Geophysics, Interferometry, Physics::Space Physics, General Earth and Planetary Sciences, Satellite, Astrophysics::Earth and Planetary Astrophysics, Electrical and Electronic Engineering, Image sensor, Moon, Remote sensing
Abstract

Moon exploitation is among the next space mission priorities. Earth observation (EO), which is traditionally implemented on artificial lower Earth orbit satellites, can be, in principle, extended to the platform constituted by the natural Earth satellite. With this regard, we investigate the features related to the EO by a possible Moon-borne synthetic aperture radar system in terms of imaging characteristics and potential applications, as well as of expected limitations.

Published
2010
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25. Four-Dimensional SAR Imaging for Height Estimation and Monitoring of Single and Double Scatterers

Author

Gianfranco Fornaro, Diego Reale, and Francesco Serafino

Subjects
Physics, Synthetic aperture radar, Pixel, business.industry, body regions, Deformation monitoring, Nonlinear system, Superposition principle, Interferometry, Optics, General Earth and Planetary Sciences, Tomography, Electrical and Electronic Engineering, business, Image resolution
Abstract

The superposition of contributions from different stable targets within the same pixel is a phenomenon that may impair the imaging and monitoring of ground scatterers via the multipass synthetic aperture radar (SAR) interferometry technique. Three-dimensional SAR imaging, also known as SAR tomography, uses multiple views to profile the scattering power at different heights. This technique has been shown to be capable of separating interfering target responses on real data. Differential SAR tomography has been recently proposed as a technique that extends the potentialities of SAR tomography to the target deformation monitoring. It performs a 4-D space-velocity imaging that enables not only separating interfering targets in elevation but also distinguishing their single slow deformation velocities. This work addresses for the first time the application of 4-D SAR imaging to real data to determine the height and mean deformation velocity of single scatterers and double-scattering mechanisms interfering at high resolution in the same pixel. It also discusses the postprocessing steps required to identify the presence of stable single and double scatterers after elevation-velocity focusing. Moreover, it proposes a technique for the extraction of time series from interfering targets to measure possible nonlinear temporal deformations.

Published
2009
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26. Imaging of Single and Double Scatterers in Urban Areas via SAR Tomography

Author

Francesco Serafino and Gianfranco Fornaro

Subjects
Synthetic aperture radar, Layover, Pixel, Computer science, Scattering, Calibration, General Earth and Planetary Sciences, Tomography, Electrical and Electronic Engineering, Microwave, Remote sensing
Abstract

Microwave scattering is a rather complex mechanism, especially in urban areas. Three-dimensional (3-D) synthetic aperture radar (SAR) tomography is a technique that uses multiple views to map the scattering power at different heights, thus extending the capability of SAR sensors to fully image the scene in the 3-D space. This paper presents a first validation of spaceborne long-term SAR tomography by demonstrating the capability to resolve a simple layover case, i.e., to separate single- and double-scattering mechanisms within imaged pixels. Results obtained with real data acquired by the European Remote Sensing 1 and 2 (ERS-1 and ERS-2) satellites over the urban area of Napoli are presented. As an additional contribution, an innovative algorithm estimating residual topography and surface deformation, called the spatial-differencing technique, is also discussed in detail at the data calibration stage

Published
2006
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27. Geometrical SAR image registration

Author

Paolo Berardino, Eugenio Sansosti, Gianfranco Fornaro, Francesco Serafino, and Michele Manunta

Subjects
Synthetic aperture radar, Pixel, business.industry, Computer science, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Image registration, synthetic aperture radar (SAR), Subpixel rendering, image registration, Interferometry, multichannel SAR, Interferometric synthetic aperture radar, General Earth and Planetary Sciences, Computer vision, Artificial intelligence, Electrical and Electronic Engineering, Image warping, business, Digital elevation model, interferometry (InSAR)
Abstract

Accurate subpixel registration of synthetic aperture radar (SAR) images is an issue that is again growing interest since its initial developments related to two-pass interferometry. Recent progress in coherent (multichannel) SAR processing raises the need for accurate registration of data takes acquired with large baseline spans, high temporal coverage, and with different frequency and/or operational modes. In this paper, we discuss a SAR image-registration procedure, based on the use of external measures which allows obtaining a very accurate alignment of SAR images. The presented technique makes use of a digital elevation model and of the precise information about the acquisition flight tracks, to compute the warping functions that map the position of each pixel in the different takes, thus avoiding any approximation. The resulting algorithm is simple, robust, precise, and very efficient; as a matter of fact, it may achieve high accuracy even in critical areas, such as steep topography regions. Moreover, the availability of an analytical and exact model allows performing a detailed sensitivity analysis that can be useful in evaluating the applicability of this technique even to future highprecision satellite systems. Extensive testing, carried out on several real European Remote Sensing and ENVISAT datasets, clearly shows the effectiveness of such algorithm in registering critical SAR images.

Published
2006
Full Text
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28. Spotlight SAR Data Focusing Based on a Two-Step Processing Approach

Author

Lanari, Riccardo, Tesauro, Manlio, Sansosti, Eugenio, and Fornaro, Gianfranco

Subjects
Synthetic aperture radar -- Analysis, Algorithms -- Models, Spectrum analysis -- Usage, Business, Earth sciences, Electronics and electrical industries
Abstract

We present a new spotlight SAR data-focusing algorithm based on a two-step processing strategy that combines the advantages of two commonly adopted processing approaches: the efficiency of SPECAN algorithms and the precision of stripmap focusing techniques. The first step of the proposed algorithm implements a linear and space-invariant azimuth filtering that is carried out via a deramping-based technique representing a simplified version of the SPECAN approach. This operation allows us to perform a bulk azimuth raw data compression and to achieve a pixel spacing smaller than (or equal to) the expected azimuth resolution of the fully focused image. Thus, the azimuth spectral folding phenomenon, typically affecting the spotlight data, is overcome, and the space-variant characteristics of the stripmap system transfer function are preserved. Accordingly, the residual and precise focusing of the SAR data is achieved by applying a conventional stripmap processing procedure requiring a minor modification and implemented in the frequency domain. The extension of the proposed technique to the case of high bandwidth transmitted chirp signals is also discussed. Experiments carried out on real and simulated data confirm the validity of the presented approach, which is mainly focused on spaceborne systems. Index Terms--Raw data focusing, spectral analysis (SPECAN) processing algorithms.

Published
2001

29. Three-dimensional focusing with multipass SAR data

Author

Francesco Soldovieri, Gianfranco Fornaro, and Francesco Serafino

Subjects
Synthetic aperture radar, Radar tracker, Scattering, business.industry, Computer science, Iterative reconstruction, Inverse problem, Superresolution, Radar imaging, Singular value decomposition, General Earth and Planetary Sciences, Computer vision, Artificial intelligence, Electrical and Electronic Engineering, business, Focus (optics), Algorithm
Abstract

Deals with the use of multipass synthetic aperture radar (SAR) data in order to achieve three-dimensional tomography reconstruction in presence of volumetric scattering. Starting from azimuth- and range-focused SAR data relative to the same area, neglecting any mutual interaction between the targets, and assuming the propagation in homogeneous media, we investigate the possibility to focus the data also in the elevation direction. The problem is formulated in the framework of linear inverse problem and the solution makes use of the singular value decomposition of the relevant operator. This allows us to properly take into account nonuniform orbit separation and to exploit a priori knowledge regarding the size of the volume interested by the scattering mechanism, thus leading to superresolution in the elevation direction. Results obtained on simulated data demonstrate the feasibility of the proposed processing technique.

Published
2003
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30. A new algorithm for surface deformation monitoring based on small baseline differential SAR interferograms

Author

Riccardo Lanari, Gianfranco Fornaro, Paolo Berardino, and Eugenio Sansosti

Subjects
Synthetic aperture radar, Data processing, GNSS augmentation, Phase (waves), Filter (signal processing), Geodesy, Interferometry, Interferometric synthetic aperture radar, General Earth and Planetary Sciences, Electrical and Electronic Engineering, Decorrelation, Algorithm, Geology, Remote sensing
Abstract

We present a new differential synthetic aperture radar (SAR) interferometry algorithm for monitoring the temporal evolution of surface deformations. The presented technique is based on an appropriate combination of differential interferograms produced by data pairs characterized by a small orbital separation (baseline) in order to limit the spatial decorrelation phenomena. The application of the singular value decomposition method allows us to easily "link" independent SAR acquisition datasets, separated by large baselines, thus increasing the observation temporal sampling rate. The availability of both spatial and temporal information in the processed data is used to identify and filter out atmospheric phase artifacts. We present results obtained on the data acquired from 1992 to 2000 by the European Remote Sensing satellites and relative to the Campi Flegrei caldera and to the city of Naples, Italy, that demonstrate the capability of the proposed approach to follow the dynamics of the detected deformations.

Published
2002
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31. Minimum mean square error space-varying filtering of interferometric SAR data

Author

Gianfranco Fornaro and Andrea Monti Guarnieri

Subjects
Synthetic aperture radar, Interferometry, Minimum mean square error, Noise (signal processing), Computer science, Radar imaging, Interferometric synthetic aperture radar, General Earth and Planetary Sciences, Filter (signal processing), Electrical and Electronic Engineering, Digital elevation model, Decorrelation, Remote sensing
Abstract

This paper addresses the problem of filtering interferometric synthetic aperture radar (IFSAR) signals in presence of nonplanar topography to mitigate geometrical decorrelation effects. The problem is space-variant. The authors assume knowledge about the scene topography and derive an optimal, minimum mean square error (MMSE), filtering procedure. The algorithm is flexible and, beside the standard stripmap-stripmap interferometry, it may be applied to IFSAR data acquired in any operative mode. For instance, in scan-scan, scan-strip, and scan-spot interferometry. The scene topography contribution may be either derived from an external rough digital elevation model (DEM) or directly estimated from the SAR data. The filtering technique is extended to the azimuth direction to account for possible Doppler centroid decorrelation. Experimental results carried out on real data confirm the validity of the theory and show that this filtering procedure allows the authors to obtain a reduction of the interferometric noise content. Its gain is particularly marked in the cases of steep topography, where application of the standard common band filters could deteriorate the signal quality, or for large Doppler centroid shifts between the two acquisitions.

Published
2002
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32. Spotlight SAR data focusing based on a two-step processing approach

Author

Gianfranco Fornaro, Riccardo Lanari, Eugenio Sansosti, and M. Tesauro

Subjects
Synthetic aperture radar, Pixel, Computer science, business.industry, Frequency domain, Radar imaging, Chirp, General Earth and Planetary Sciences, Computer vision, Artificial intelligence, Electrical and Electronic Engineering, business
Abstract

The authors present a new spotlight SAR data-focusing algorithm based on a two-step processing strategy that combines the advantages of two commonly adopted processing approaches: the efficiency of SPECAN algorithms and the precision of stripmap focusing techniques. The first step of the proposed algorithm implements a linear and space-invariant azimuth filtering that is carried out via a deramping-based technique representing a simplified version of the SPECAN approach. This operation allows the authors to perform a bulk azimuth raw data compression and to achieve a pixel spacing smaller than (or equal to) the expected azimuth resolution of the fully focused image. Thus, the azimuth spectral folding phenomenon, typically affecting the spotlight data, is overcome, and the space-variant characteristics of the stripmap system transfer function are preserved. Accordingly, the residual and precise focusing of the SAR data is achieved by applying a conventional stripmap processing procedure requiring a minor modification and implemented in the frequency domain. The extension of the proposed technique to the case of high bandwidth transmitted chirp signals is also discussed. Experiments carried out on real and simulated data confirm the validity of the presented approach, which is mainly focused on spaceborne systems.

Published
2001
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33. A two-dimensional region growing least squares phase unwrapping algorithm for interferometric SAR processing

Author

Gianfranco Fornaro and Eugenio Sansosti

Subjects
Synthetic aperture radar, Interferometry, Propagation of uncertainty, Computer science, Region growing, Radar imaging, Phase (waves), General Earth and Planetary Sciences, Boundary (topology), Electrical and Electronic Engineering, Algorithm, Least squares, Finite element method
Abstract

This paper presents a new two-dimensional (2-D) phase unwrapping (PhU) algorithm based on a least squares (LS) region growing strategy: the wrapped phase image is partitioned in different regions that are sequentially unwrapped via a LS algorithm. Reliable regions are dealt with at the beginning of the procedure, while critical areas are unwrapped in the final steps, thus avoiding error propagation from critical to reliable areas. A conditioned least squares formulation of the phase unwrapping problem is the core of the proposed procedure: this allows the solution to be tied to "some" known boundary phase values, thus guaranteeing the correct joining of the reconstructed phase in between the different regions and preventing them from being independently unwrapped. The application of the finite element method allows a straightforward implementation of the algorithm in the discrete domain case. Experimental results, carried out on simulated and real interferometric SAR data, show the effectiveness of the proposed algorithm and the improved performances with respect to existing unwrapping procedures.

Published
1999
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34. Synthetic aperture radar interferometry using one bit coded raw and reference signals

Author

Gilda Schirinzi, Vito Pascazio, and Gianfranco Fornaro

Subjects
Synthetic aperture radar, Upsampling, Interferometry, Computer science, Radar imaging, General Earth and Planetary Sciences, Electrical and Electronic Engineering, Signal, Algorithm, Image (mathematics), Remote sensing
Abstract

This paper is concerned about the generation of interferometric phase patterns using synthetic aperture radar (SAR) images obtained by processing the raw data and reference function both quantized at one bit (Signum Coded). Such processing technique involves one-bit coded (i.e., binary) sequences, and can be efficiently implemented in real time using very simple and low cost hardware. It is shown that the proposed SC processing technique preserves, besides the image intensities, also interferometric phase patterns, before and after phase unwrapping. To test the performance of the proposed technique, experiments have been carried out on real data relative to the ERS-1 mission. Quantitative comparison between the results of conventional and SC processing clearly show that the presented method can be used for quick-look DEMs generation. Moreover, in accordance with the SC-SAR theory, an upsampling has also been performed on the signals to be processed to obtain higher quality patterns. This produce a noticeable improvement of the obtained results, so that the SC techniques can be considered a valid alternative to the conventional ones, still preserving the advantages in terms of real time.

Published
1997
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35. A short discussion on the exact compensation of the SAR range-dependent range cell migration effect

Author

Gianfranco Fornaro and Riccardo Lanari

Subjects
Synthetic aperture radar, Computer science, Range (statistics), Chirp, General Earth and Planetary Sciences, Electrical and Electronic Engineering, Algorithm, Compensation (engineering), Remote sensing
Abstract

Efficient and precise compensation of the range cell migration (RCM) effect is a key point for a fast and accurate synthetic aperture radar (SAR) data processor. In particular the range-dependent nature of the range cell migration effect complicates the compensation operation. It has been recently shown that an exact compensation of the range-dependent RCM (RDRCM) phenomenon can be carried out either by applying the chirp scaling algorithm or the chirp z-transform procedure. This paper investigates the relationship between the two methods. In particular, it is shown that the chirp z-transform based approach represents a particular implementation of the chirp scaling algorithm. A final discussion is dedicated to show how the chirp z-transform and the chirp scaling procedure can be applied within a SAR data processing algorithm.

Published
1997
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36. Interferometric SAR phase unwrapping using Green's formulation

Author

Giorgio Franceschetti, Gianfranco Fornaro, and Riccardo Lanari

Subjects
Synthetic aperture radar, Signal processing, business.industry, Computer science, Phase (waves), Image processing, Interference (wave propagation), Inverse synthetic aperture radar, Interferometry, Optics, Radar imaging, Phase noise, Interferometric synthetic aperture radar, General Earth and Planetary Sciences, Electrical and Electronic Engineering, business, Algorithm
Abstract

Any method that permits retrieving full range (unwrapped) phase values starting from their (-/spl pi/,/spl pi/) determination (wrapped phase) can be defined as a phase unwrapping technique. This paper addresses a new procedure for phase unwrapping especially designed for interferometric synthetic aperture radar applications. The proposed algorithm is based on use of Green's first identity. Results on simulated as well as on real data are presented. They both confirm the excellent performance of the procedure.

Published
1996
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44. X-SAR interferometry: first results

Author

Moreira, J., primary, Schwabisch, M., additional, Fornaro, G., additional, Lanari, R., additional, Bamler, R., additional, Just, D., additional, Steinbrecher, U., additional, Breit, H., additional, Eineder, M., additional, Franceschetti, G., additional, Geudtner, D., additional, and Rinkel, H., additional

Published
1995
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