Your search keyword '"Bianchini, Silvia"' showing total 10 results

1. Satellite Radar Interferometry for Monitoring Historic Urban Fabric: Lucca and Florence Test Cities

Author

Bianchini, Silvia, Festa, Davide, Öchsner, Andreas, Series Editor, da Silva, Lucas F. M., Series Editor, Altenbach, Holm, Series Editor, Furferi, Rocco, editor, Giorgi, Rodorico, editor, Seymour, Kate, editor, and Pelagotti, Anna, editor

Published

2022

2. SATELLITE RADAR INTERFEROMETRY FOR THE ANALYSIS OF POTENTIAL INSTABILITY IN URBAN AREAS OF HIGH HISTORICAL AND CULTURAL VALUE.

Author

PALAMIDESSI, ANNA, BIANCHINI, SILVIA, CENTAURO, IRENE, TOFANI, VERONICA, TAPETE, DEODATO, and VIRELLI, MARIA

Subjects

REMOTE sensing by radar, SCIENTIFIC literature, SYNTHETIC aperture radar, RADAR interferometry, DEFORMATION potential

Abstract

Satellite radar remote sensing techniques are non-invasive methodologies that can be effectively used for diagnostic purposes, measuring displacements, and monitoring cultural assets, architectural structures, and archaeological areas without injuring their integrity. The environmental condition and hydrogeological hazard in the Italian territory could make its invaluable Cultural Heritage at risk. Therefore, within the National Extraordinary Plan for Monitoring and Conservation of Cultural Heritage, an agreement has been established between the Ministry of Culture and the UNESCO Chair of the UNiversity of Florence on Prevention and Sustainable Management of Geo-hydrological Hazard to analyse ground motion rates on built-up areas by means of acquisition and PSI (Persistent Scatterers Interferometry) elaboration of high-resolution CosmoSkyMed synthetic aperture radar (SAR) satellite data (X-band). This technique can provide useful support on the conservation and protection of Cultural Heritage, as it endorses an innovative perspective on the condition and safety of historical sites, monuments, archaeological sites and artworks, thus contributing significantly to their preservation over time. Through SAR interferometric techniques, it is possible to identify millimetric displacements related to environmental threats, such as slow-moving landslides. This work proposes the classification of buildings of urban areas by using two indices based on PSI data coverage and deformation rates: the data coverage index in each building (Id) and the average velocity index of PSI data in each building and its surroundings (Ivmean), representing deformation rates in a locally scaled, easily understandable color-coded format. This method has already been tested in scientific literature on other SAR datasets for evaluating instability at the building scale. The approach aims to develop a fast and low-cost system to assess buildings that are potentially exposed to deformation and therefore more susceptible to damage in heavily urbanized areas with high historical-cultural value. In order to safeguard Cultural Heritage from natural disasters, the proposed methodology integrates a high degree of scientific and technological expertise and presents an updated and accurate screening of potential deformations due to hydrogeological hazards. [ABSTRACT FROM AUTHOR]

Published

2024

3. Detecting Slope and Urban Potential Unstable Areas by Means of Multi-Platform Remote Sensing Techniques: The Volterra (Italy) Case Study.

Author

Nolesini, Teresa, Frodella, William, Bianchini, Silvia, and Casagli, Nicola

Subjects

CULTURAL property, SOIL erosion, METROPOLITAN areas, LANDSLIDES, AERIAL surveillance

Abstract

Volterra (Central Italy) is a town of great historical interest, due to its vast and well-preserved cultural heritage, including a 2.6 km long Etruscan-medieval wall enclosure representing one of the most important elements. Volterra is located on a clayey hilltop prone to landsliding, soil erosion, therefore the town is subject to structural deterioration. During 2014, two impressive collapses occurred on the wall enclosure in the southwestern urban sector. Following these events, a monitoring campaign was carried out by means of remote sensing techniques, such as space-borne (PS-InSAR) and ground-based (GB-InSAR) radar interferometry, in order to analyze the displacements occurring both in the urban area and the surrounding slopes, and therefore to detect possible critical sectors with respect to instability phenomena. Infrared thermography (IRT) was also applied with the aim of detecting possible criticalities on the wall-enclosure, with special regards to moisture and seepage areas. PS-InSAR data allowed a stability back-monitoring on the area, revealing 19 active clusters displaying ground velocity higher than 10 mm/year in the period 2011-2015. The GB-InSAR system detected an acceleration up to 1.7 mm/h in near-real time as the March 2014 failure precursor. The IRT technique, employed on a double survey campaign, in both dry and rainy conditions, permitted to acquire 65 thermograms covering 23 sectors of the town wall, highlighting four thermal anomalies. The outcomes of this work demonstrate the usefulness of different remote sensing technologies for deriving information in risk prevention and management, and the importance of choosing the appropriate technology depending on the target, time sampling and investigation scale. In this paper, the use of a multi-platform remote sensing system permitted technical support of the local authorities and conservators, providing a comprehensive overview of the Volterra site, its cultural heritage and landscape, both in near-real time and back-analysis and at different scales of investigation. [ABSTRACT FROM AUTHOR]

Published

2016

4. Multi-Temporal Evaluation of Landslide Movements and Impacts on Buildings in San Fratello (Italy) By Means of C-Band and X-Band PSI Data.

Author

Bianchini, Silvia, Ciampalini, Andrea, Raspini, Federico, Bardi, Federica, Di Traglia, Federico, Moretti, Sandro, and Casagli, Nicola

Subjects

LANDSLIDE hazard analysis, RISK assessment for landslides, RADAR interferometry, SYNTHETIC aperture radar, SPATIAL variation

Abstract

This work provides a multi-temporal and spatial investigation of landslide effects in the San Fratello area (Messina province within the Sicily region, Italy), by means of C-band and X-band Persistent Scatterer Interferometry (PSI) data, integrated with in situ field checks and a crack pattern survey. The Sicily region is extensively affected by hydrogeological hazards since several landslides regularly involved local areas across time. In particular, intense and catastrophic landslide phenomena have recently occurred in the San Fratello area; the last event took place in February 2010, causing large economic damage. Thus, the need for an accurate ground motions and impacts mapping and monitoring turns out to be significantly effective, in order to better identify active unstable areas and to help proper risk-mitigation measures planning. The combined use of historical and recent C-band satellites and current X-band Synthetic Aperture Radar sensors of a new generation permits spatially and temporally detection of landslide-induced motions on a local scale and to properly provide a complete multi-temporal evaluation of their effects on the area of interest. PSI ground motion rates are cross-compared with local failures and damage of involved buildings, recently recognized by in situ observations. As a result, the analysis of landslide-induced movements over almost 20 years and the validation of radar data with manufactured crack patterns, permits one to finally achieve a complete and reliable assessment in the San Fratello test site. [ABSTRACT FROM AUTHOR]

Published

2015

5. Analysis of recent ground subsidence in the Sibari plain (Italy) by means of satellite SAR interferometry-based methods.

Author

Bianchini, Silvia and Moretti, Sandro

Subjects

*LAND subsidence, *SYNTHETIC aperture radar, *RADAR interferometry, *GEOLOGIC faults, *GEODETIC observations, *GEOMORPHOLOGY, *GEOTECHNICAL engineering, *MATHEMATICAL models

Abstract

This work attempts to map recent land subsidence on the Sibari plain in Calabria region (Southern Italy), by exploiting vertical velocity values and time series of persistent scatterer interferometry (PSI) synthetic aperture radar (SAR) data acquired in the period 1992–2011 by different satellite systems. After reviewing other sources and rates of subsidence recorded by previous works since the beginning of the Holocene, this paper presents the spatial distribution of the current settlement rates showing that subsidence is due to the compressible alluvial sediments of the plain, but that in recent times it is mostly due also to human activities. In fact, according to the most recent monitoring period (2009–2011), downward motion rates are recorded as being only localized within site-specific industrial areas, such as the ‘Sibari Lakes’ nautical and residential centre and Corigliano Calabro Industrial Zone. The temporal analysis of persistent scatterers (PS) time series, carried out through the PS-Time program, adds further useful information, finally highlighting that, in these areas, subsidence has positively decreased or stabilized from the second semester of the year 2010. This work shows that PSI measurements provide support in the quantitative evaluation of known subsidence process and that the analysis of time series allows effective detection of the temporal evolution trends of the phenomenon, such as changes or deceleration in displacement rates, not otherwise visible by merely considering the average velocity. [ABSTRACT FROM PUBLISHER]

Published

2015

6. Exploitation of Large Archives of ERS and ENVISAT C-Band SAR Data to Characterize Ground Deformations.

Author

Ventisette, Chiara Del, Ciampalini, Andrea, Manunta, Michele, Calò, Fabiana, Paglia, Luca, Ardizzone, Francesca, Mondini, Alessandro Cesare, Reichenbach, Paola, Mateos, Rosa Maria, Bianchini, Silvia, Garcia, Immaculada, Füsi, Balázs, Deák, Zsuzsa Villő, Rádi, Károly, Graniczny, Marek, Kowalski, Zbigniew, Piatkowska, Anna, Przylucka, Maria, Hugo Retzo, and Tazio Strozzi

Subjects

RADAR, RADAR interferometry, VOLCANIC activity prediction, DORIS

Abstract

In the last few years several advances have been made in the use of radar images to detect map monitor ground deformations. DInSAR (Differential Synthetic Aperture Radar Interferometry) A-DInSAR/PSI (Advanced DInSAR/Persistent Scatterers Interferometry) technologies have been successfully applied in the study of deformation phenomena induced by for example active tectonics volcanic activity ground water exploitation mining landslides both at local regional scales. In this paper the existing European Space Agency (ESA) archives (acquired as part of the FP -DORIS project) which were collected by the ERS- / ENVISAT satellites operating in the microwave C-band were analyzed exploited to understand the dynamics of landslide subsidence phenomena. In particular this paper presents the results obtained as part of the FP -DORIS project to demonstrate that the full exploitation of very long deformation time series (more than years) can play a key role in understanding the dynamics of natural human-induced hazards. [ABSTRACT FROM AUTHOR]

Published

2013

7. Review of Works Combining GNSS and InSAR in Europe.

Author

Del Soldato, Matteo, Confuorto, Pierluigi, Bianchini, Silvia, Sbarra, Paolo, Casagli, Nicola, and Palano, Mimmo

Subjects

GLOBAL Positioning System, SYNTHETIC aperture radar, SCIENTIFIC knowledge, RADAR interferometry, REMOTE sensing

Abstract

The Global Navigation Satellite System (GNSS) and Synthetic Aperture Radar Interferometry (InSAR) can be combined to achieve different goals, owing to their main principles. Both enable the collection of information about ground deformation due to the differences of two consequent acquisitions. Their variable applications, even if strictly related to ground deformation and water vapor determination, have encouraged the scientific community to combine GNSS and InSAR data and their derivable products. In this work, more than 190 scientific contributions were collected spanning the whole European continent. The spatial and temporal distribution of such studies, as well as the distinction in different fields of application, were analyzed. Research in Italy, as the most represented nation, with 47 scientific contributions, has been dedicated to the spatial and temporal distribution of its studied phenomena. The state-of-the-art of the various applications of these two combined techniques can improve the knowledge of the scientific community and help in the further development of new approaches or additional applications in different fields. The demonstrated usefulness and versability of the combination of GNSS and InSAR remote sensing techniques for different purposes, as well as the availability of free data, EUREF and GMS (Ground Motion Service), and the possibility of overcoming some limitations of these techniques through their combination suggest an increasingly widespread approach. [ABSTRACT FROM AUTHOR]

Published

2021

8. Regional Recognition and Classification of Active Loess Landslides Using Two-Dimensional Deformation Derived from Sentinel-1 Interferometric Radar Data.

Author

Meng, Qingkai, Confuorto, Pierluigi, Peng, Ying, Raspini, Federico, Bianchini, Silvia, Han, Shuai, Liu, Haocheng, and Casagli, Nicola

Subjects

LANDSLIDES, LOESS, SYNTHETIC aperture radar, LANDSLIDE hazard analysis, RADAR interferometry, HAZARD mitigation

Abstract

Identification and classification of landslides is a preliminary and crucial work for landslide risk assessment and hazard mitigation. The exploitation of surface deformation velocity derived from satellite synthetic aperture radar interferometry (InSAR) is a consolidated and suitable procedure for the recognition of active landslides over wide areas. However, the calculated displacement velocity from InSAR is one-dimensional motion along the satellite line of sight (LOS), representing a major hurdle for landslide type and failure mechanism classification. In this paper, different velocity datasets derived from both ascending and descending Sentinel-1 data are employed to analyze the surface ground movement of the Huangshui region (Northwestern China). With global warming, precipitation in the Huangshui region, geologically belonging to the loess basin in the eastern edge of Qing-Tibet Plateau, has been increasing, often triggering a large number of landslides, posing a potential threat to local citizens and natural and anthropic environments. After processing both SAR data geometries, the surface motion was decomposed to obtain the two-dimensional displacements (vertical and horizontal E–W). Thus, a classification criterion of the loess landslide types and failure mode is proposed, according to the analysis of deformation direction, velocities, texture, and topographic characteristics. With the support of high-resolution images acquired by remote sensing and unmanned aerial vehicle (UAV), 14 translational slides, seven rotational slides, and 10 loess flows were recognized in the study area. The derived results may provide solid support for stakeholders to comprehend the hazard of unstable slopes and to undertake specific precautions for moderate and slow slope movements. [ABSTRACT FROM AUTHOR]

Published

2020

9. Satellite interferometric data for landslide intensity evaluation in mountainous regions.

Author

Solari, Lorenzo, Bianchini, Silvia, Franceschini, Rachele, Barra, Anna, Monserrat, Oriol, Thuegaz, Patrick, Bertolo, Davide, Crosetto, Michele, and Catani, Filippo

Subjects

*LANDSLIDES, *RADAR interferometry, *SYNTHETIC aperture radar

Abstract

• Satellite interferometric data as tools for landslide intensity estimation. • Intensity as input for landslide potential loss calculation. • Regional scale approach fully relying on interferometric data. • Combination of interferometric data and gravitational process models. Multi-Temporal Interferometric Synthetic Aperture Radar (MTInSAR) data offer a valuable support to landslide mapping and to landslide activity estimation in mountain environments, where in situ measures are sometimes difficult to gather. Nowadays, the interferometric approach is more and more used for wide-areas analysis, providing useful information for risk management actors but at the same time requiring a lot of efforts to correctly interpret what satellite data are telling us. In this context, hot-spot-like analyses that select and highlight the fastest moving areas in a region of interest, are a good operative solution for reducing the time needed to inspect a whole interferometric dataset composed by thousands or millions of points. In this work, we go beyond the concept of MTInSAR data as simple mapping tools by proposing an approach whose final goal is the quantification of the potential loss experienced by an element at risk hit by a potential landslide. To do so, it is mandatory to evaluate landslide intensity. Here, we estimate intensity using Active Deformation Areas (ADA) extracted from Sentinel-1 MTInSAR data. Depending on the localization of each ADA with respect to the urban areas, intensity is derived in two different ways. Once exposure and vulnerability of the elements at risk are estimated, the potential loss due to a landslide of a given intensity is calculated. We tested our methodology in the Eastern Valle d'Aosta (north-western Italy), along four lateral valleys of the Dora Baltea Valley. This territory is characterized by steep slopes and by numerous active and dormant landslides. The goal of this work is to develop a regional scale methodology based on satellite radar interferometry to assess the potential impact of landslides on the urban fabric. [ABSTRACT FROM AUTHOR]

Published

2020

10. Review of satellite radar interferometry for subsidence analysis.

Author

Raspini, Federico, Caleca, Francesco, Del Soldato, Matteo, Festa, Davide, Confuorto, Pierluigi, and Bianchini, Silvia

Subjects

*RADAR interferometry, *INTERFEROMETRY, *LAND subsidence, *WEB search engines, *SCIENTIFIC literature, *SPACE-based radar, *REMOTE-sensing images

Abstract

This paper includes a critical review of the existing literature on the use of satellite SAR imagery for subsidence analysis. Land subsidence, related to multiple natural and human-induced processes, is observed globally in an increasing number of areas. Potentially leading to severe impacts on economics and the environment, subsidence has attracted growing scientific attention and, over the last decades, new tools and methods have been developed for accurately measuring the spatial and temporal evolution of surface deformations associated with subsidence phenomena. The collection of the existing scientific literature on the satellite InSAR for subsidence analysis was conducted in January 2022 exploiting the WoS's freely accessible web search engine. An extensive database of 1059 scientific contributions was compiled, covering the period 1997–2021. The content of each record in the literature database has been critically examined to collect and store information regarding the study area location, microwave band adopted, satellite used, processing approach, subsidence cause, application type, field evidence and strategies to validate and compare InSAR data. Analysis of temporal distribution revealed a substantial growth in scientific production and an increasing interest of geoscientists, with a mean value of 21 articles per year from 1997 to 2014, rising to about 100 articles per year between 2015 and 2021. All continents include at least a study area, with Asia and Europe having the largest number of case studies, with 586 and 281 analyses in their territory, respectively, and revealing a clear geographical bias in subsidence study locations. Graphical visualizations and syntheses of current applications are presented. The large availability of different acquisition bands, the increasing imaging capabilities, refinement of processing approaches, and growing expertise in data interpretation allowed InSAR data to be used at different scales of analysis, for different purposes and subsidence types, in a wide range of physiographic settings. This review highlights that satellite InSAR has moved from being a niche topic to an operative tool with a major role in subsidence studies. Despite more than 25 years of progress and advancements, technical and operational challenges remain to be faced. Leveraging on the analysis of the literature review and authors' experience, recommendations and perspectives are provided for a more effective use of InSAR data. [ABSTRACT FROM AUTHOR]

Published

2022