Your search keyword '"Scaioni, Marco"' showing total 174 results

151. Landslide Investigation with Remote Sensing and Sensor Network: From Susceptibility Mapping and Scaled-down Simulation towards in situ Sensor Network Design.

Author

Gang Qiao, Ping Lu, Scaioni, Marco, Shuying Xu, Xiaohua Tong, Tiantian Feng, Hangbin Wu, Wen Chen, Yixiang Tian, Weian Wang, and Rongxing Li

Subjects

LANDSLIDE prediction, ATMOSPHERIC effects on remote sensing, SENSOR networks, OPTICAL susceptibility, ARTIFICIAL neural networks, WENCHUAN Earthquake, China, 2008

Abstract

This paper presents an integrated approach to landslide research based on remote sensing and sensor networks. This approach is composed of three important parts: (i) landslide susceptibility mapping using remote-sensing techniques for susceptible determination of landslide spots; (ii) scaled-down landslide simulation experiments for validation of sensor network for landslide monitoring, and (iii) in situ sensor network deployment for intensified landslide monitoring. The study site is the Taziping landslide located in Hongkou Town (Sichuan, China). The landslide features generated by landslides triggered by the 2008 Wenchuan Earthquake were first extracted by means of object-oriented methods from the remote-sensing images before and after the landslides events. On the basis of correlations derived between spatial distribution of landslides and control factors, the landslide susceptibility mapping was carried out using the Artificial Neural Network (ANN) technique. Then the Taziping landslide, located in the above mentioned study area, was taken as an example to design and implement a scaled-down landslide simulation platform in Tongji University (Shanghai, China). The landslide monitoring sensors were carefully investigated and deployed for rainfall induced landslide simulation experiments. Finally, outcomes from the simulation experiments were adopted and employed to design the future in situ sensor network in Taziping landslide site where the sensor deployment is being implemented. [ABSTRACT FROM AUTHOR]

Published

2013

152. High-resolution texturing of building facades with thermal images

Author

Scaioni, Marco, Rosina, Elisabetta, Barazzetti, Luigi, Previtali, Mattia, and Redaelli, Veronica

Abstract

This paper presents two methodologies able to map a block of IR thermal and RGB images on 3D models derived from terrestrial laser scanning surveying. Proposed methods stand out from other traditional approaches that are mainly based on the projection of single images through approximate models. The first method is a rigorous photogrammetric orientation through a bundle adjustment integrating both RGB and thermal data. Then, another complementary solution based on the use of a calibrated 'bi-camera' system is illustrated. Both methods allows one to texture building facades (reconstructed with 3D models) with their temperature values. Finally, several products can be extracted and managed in different data processing environments: triangulated models to visualize 3D spatial information and to analyze 3D heating diffusion on the surface; raster datasets (e.g. orthophotos or rectified images) with temperature as radiometric value. Both approaches were tested on different buildings of Politecnico di Milano University, where a restoration project of historical and modern facades is currently work in progress.

Published

2012

153. Coarse-to-Fine Classification of Road Infrastructure Elements from Mobile Point Clouds Using Symmetric Ensemble Point Network and Euclidean Cluster Extraction.

Author

Wang, Duo, Wang, Jin, Scaioni, Marco, and Si, Qi

Subjects

POINT cloud, PAVEMENTS, TRAFFIC signs & signals, SYMMETRIC functions, TRANSPORTATION management, RADARSAT satellites

Abstract

Classifying point clouds obtained from mobile laser scanning of road environments is a fundamental yet challenging problem for road asset management and unmanned vehicle navigation. Deep learning networks need no prior knowledge to classify multiple objects, but often generate a certain amount of false predictions. However, traditional clustering methods often involve leveraging a priori knowledge, but may lack generalisability compared to deep learning networks. This paper presents a classification method that coarsely classifies multiple objects of road infrastructure with a symmetric ensemble point (SEP) network and then refines the results with a Euclidean cluster extraction (ECE) algorithm. The SEP network applies a symmetric function to capture relevant structural features at different scales and select optimal sub-samples using an ensemble method. The ECE subsequently adjusts points that have been predicted incorrectly by the first step. The experimental results indicate that this method effectively extracts six types of road infrastructure elements: road surfaces, buildings, walls, traffic signs, trees and streetlights. The overall accuracy of the SEP-ECE method improves by 3.97% with respect to PointNet. The achieved average classification accuracy is approximately 99.74 % , which is suitable for practical use in transportation network management. [ABSTRACT FROM AUTHOR]

Published

2020

154. Measurement of Surface Changes in a Scaled-Down Landslide Model Using High-Speed Stereo Image Sequences.

Author

Tiantian Feng, Huan Mi, Scaioni, Marco, Gang Qiao, Ping Lu, Weian Wang, Xiaohua Tong, and Rongxing Li

Subjects

SURFACE area measurement, LANDSLIDES, STEREO image processing, SINGLE-lens reflex cameras, CARTOGRAPHY, HIGHER education

Abstract

Construction of scaled-down landslide models is an important means for landslide study. The objective of this study is to develop an innovative non-contact photogrammetric system to meet the challenge for monitoring the fast surface deformation of a laboratory-simulated landslide, which can detect pre-failure events and the final failure, provide sectional and overall surface deformation patterns, and generate speed maps during the rapid slope failure. We proposed an event detector based on altered surface features in the slower SLRC (single-lens-reflex camera) image sequence to detect pre-failure events, while a combined analysis tool used the surface velocity fields and deformation areas based on fast HSCS (high-speed stereo-camera system) stereo image sequences to reveal fast-changing landslide behavior during the short final failure. The introduced surface change detector uses the percentage of sliding block areas, percentage of changed features, and average speeds. It successfully detected four pre-failure local collapse events and the final slope failure; the extent of surface changes reached its maximum to accumulate energy 1.5 seconds before the failure when the average speed of changed features achieved its peak of 0.8 m/s. The developed system achieved a position accuracy of 3.8 mm and a speed accuracy of 0.11 m/s. The analysis result demonstrated a time period of 66 minutes before the failure which is confirmed by significant signals from both imaging and contact sensors and is important for landslide early warning. A field implementation scheme in western China will be designed and realized in the near future. [ABSTRACT FROM AUTHOR]

Published

2016

155. Radiometric normalization with multi-image pseudo-invariant features

Author

Themistocleous, Kyriacos, Hadjimitsis, Diofantos G., Michaelides, Silas, Papadavid, Giorgos, Barazzetti, Luigi, Gianinetto, Marco, and Scaioni, Marco

Published

2016

156. Mosaicking thermal images of buildings

Author

Remondino, Fabio, Shortis, Mark R., Beyerer, Jürgen, Puente León, Fernando, Barazzetti, Luigi, Erba, Silvia, Previtali, Mattia, Rosina, Elisabetta, and Scaioni, Marco

Published

2013

157. The Project to Complete the Regional Topographic Geodatabase in Lombardy, Italy.

Author

Belotti, Piera, Conzi, Fabio, Dell'Orto, Chiara, Federici, Maurizio, Fregonese, Luigi, Garnero, Gabriele, Guastamacchia, Emilio, Guzzetti, Franco, Pinto, Livio, and Scaioni, Marco

Subjects

*TOPOGRAPHY, *GEODATABASES, *CARTOGRAPHY, *REGIONAL planning, *URBAN planning

Abstract

The Regional Topographic Geodatabase (DBTR) was officially defined in 2005 as the multi-scale (1:1,000 – 1:2,000 – 1:5,000 – 1:10,000) cartographic reference for urban and regional planning in Lombardy Region. The DBTR had been previously introduced at national level to take over traditional numerical topographic maps adopted for urban planning, with the aim to provide a base map to be implemented either at regional level (Regional Geoportal) and by local administrations. The DBTR is structured by following some national guidelines that define either the content and the topological structure, that makes simple its implementation in GIS environment. The construction of the entire DBTR has historically gone through different phases, with the consistent support of the regional subsidiary policy. But when the effects of the world economic crisis in 2008 became tangible in the budget of public administrations, the growth of the project faced an important break. In 2017 the administration of Lombardy Region has promoted and financed a new project finalized to the completion of the DBTR. A temporary association of mapping companies won the tender and completed the project by summer 2020, despite of the difficulties related to the COVID-19 pandemic. A team led by Politecnico di Milano was appointed for the quality assessment. The proposed paper would like to present this project and the operational solutions applied for the production of the new subsections of the DBTR, as well as its quality assessment/validation. [ABSTRACT FROM AUTHOR]

Published

2021

158. Monitoring Landslide Activities in the Three Gorges Area with Multi-frequency Satellite SAR Data Sets

Author

Zhang, Lu, Liao, Mingsheng, Balz, Timo, Shi, Xuguo, Jiang, Yanan, and Scaioni, Marco, editor

Published

2015

159. Radar Technologies for Landslide Detection, Monitoring, Early Warning and Emergency Management

Author

Del Ventisette, Chiara, Gigli, Giovanni, Tofani, Veronica, Lu, Ping, Casagli, Nicola, and Scaioni, Marco, editor

Published

2015

160. Predictability of a Physically Based Model for Rainfall-induced Shallow Landslides: Model Development and Case Studies

Author

Hong, Yang, He, Xiaogang, Cerato, Amy, Zhang, Ke, Hong, Zhen, Liao, Zonghu, and Scaioni, Marco, editor

Published

2015

161. A Fixed Terrestrial Photogrammetric System for Landslide Monitoring

Author

Roncella, Riccardo, Forlani, Gianfranco, and Scaioni, Marco, editor

Published

2015

162. The State of the Art of SPH Modelling for Flow-slide Propagation

Author

Dai, Zili, Huang, Yu, and Scaioni, Marco, editor

Published

2015

163. A New Approach Based on Terrestrial Remote-sensing Techniques for Rock Fall Hazard Assessment

Author

Mazzanti, Paolo, Brunetti, Alessandro, Bretschneider, Alberto, and Scaioni, Marco, editor

Published

2015

164. Micro-scale Landslide Displacements Detection Using Bayesian Methods Applied to GNSS Data

Author

Pirotti, Francesco, Guarnieri, Alberto, Masiero, Andrea, Gregoretti, Carlo, Degetto, Massimo, Vettore, Antonio, and Scaioni, Marco, editor

Published

2015

165. Analysis of Microseismic Activity Within Unstable Rock Slopes

Author

Arosio, Diego, Longoni, Laura, Papini, Monica, Zanzi, Luigi, and Scaioni, Marco, editor

Published

2015

166. Multi-temporal Terrestrial Laser Scanning Survey of a Landslide

Author

Barbarella, Maurizio, Fiani, Margherita, Lugli, Andrea, and Scaioni, Marco, editor

Published

2015

167. High-resolution spectroscopy for detecting stratigraphic surfaces and stacking patterns in sedimentary basins.

Author

Souza, Marcelo Kehl De, Tognoli, Francisco Manoel Wohnrath, Veronez, Maurício Roberto, De Oliveira, Luiz Paulo Luna, Gonzaga, Luiz, Cagliari, Joice, and Scaioni, Marco

Subjects

*HIGH resolution spectroscopy, *STRATIGRAPHIC geology, *SEDIMENTARY basins, *WAVELENGTHS, *CARBONATES, *SEDIMENTOLOGY

Abstract

Abstract In this research was evaluated the potential of using scores derived from spectral data to detect surfaces and stacking patterns in the sedimentary record, and propose a new method for analyzing spectral data. Spectral field surveys with wavelengths ranging between 2.0 and 2.5 μm were acquired from three well-exposed outcrops in the Neuquén Basin, Argentina. The sedimentary succession surveyed in this area presents a continuous exposure up to 600 m thick and comprises both pure and hybrid siliciclastic, carbonate and evaporitic rocks. Reflectance data obtained from this area were processed by multivariate analysis, which demonstrates that almost all of the data variance is represented by the first principal component. Inflections of the scores' derivatives can be used to identify stratigraphic surfaces and as an indicator of stacking patterns. Overall, these results demonstrate that fast, inexpensive and non-destructive spectral data are useful tools in the fields of sedimentology and stratigraphy, which have the potential to eventually support more complex and detailed hyperspectral stratigraphy research. Highlights • Hyperspectral data for sedimentological and stratigraphical analyses. • Original and innovative approach to characterize sedimentary successions. • Score derivative allowed identifying stacking patterns and stratigraphic surfaces. [ABSTRACT FROM AUTHOR]

Published

2018

168. Experimental Investigation of the Applicability of W-Band MIMO-SAR for Structural Health Monitoring

Author

Baumann-Ouyang, Andreas, Wieser, Andreas, Scaioni, Marco, and Butt, Jemil Avers

Subjects

W-band, Interferometery, Monitoring, FMCW radar, SHM, Algorithm, Data processing, computer science, MIMO-SAR, Wind Turbine, Bridge, 3D displacement vector field, least squares adjustment (LSQ), Engineering & allied operations, ddc:620, ddc:004

Abstract

Due to constant exposure to environmental conditions and external forces, engineering structures like bridges, high-rise buildings, and others deteriorate over time. Structural Health Monitoring (SHM) aims to identify and locate potential damages that could cause a change in the system’s integrity. Identification can help reduce costs by initiating timely maintenance and extending the structure’s lifetime. Engineers use various types of sensors (e.g. accelerometers, strain gauges, etc.) to assess the structure’s condition. Most systems provide a time series of observations at the sensor’s location. Covering large structures would require the costly installation of multiple sensors and wiring a network for acquisition management. MIMO-SAR, short for Multiple Input Multiple Output Synthetic Aperture Radar, systems are an emerging alternative. By emitting a frequency-modulated continuous wave (FMCW), such systems can use Terrestrial Radar Interferometry (TRI) to measure highly accurately the displacements of an object at high temporal and spatial resolution. However, the effects impacting the performance of MIMO-SAR systems are yet not well understood for practical applications. In this thesis, the applicability of W-band MIMO-SAR for SHM has been investigated. More specifically, the effects impacting the accuracy of a commercial low-cost, automotive MIMO-SAR system have been analysed. Experiments carried out in indoor and outdoor environments under adverse weather conditions have been used to analyse and quantify the impact of measurement noise, short-term drifts due to clock instabilities, meteorological variations, and electromagnetic interference caused by a second active MIMO-SAR system on displacement measurements. This was followed by assessing the capabilities of a MIMO-SAR system for a real-case application, i.e. deformation of a railway bridge under traffic load and deformation of a wind turbine tower under working load. The investigation was rounded off by developing an algorithm to derive 3D displacement vectors from a set of line-of-sight displacements as it is given by TRI. Those algorithms performed least-square adjustments which took into account the spatial or temporal correlations of the observations. The results show that W-Band MIMO-SAR sensors can be used to measure short-term line-of-sight displacement with low uncertainties (tens of micrometres) and high temporal resolution (milliseconds). The system configuration used in these investigations allowed 2D mapping of the displacements of objects located up to 175 metres with high angular (approx. 1.4 degrees) and range (up to 4 centimetres) resolution. Furthermore, measurements acquired by three simultaneously operating MIMO-SAR sensors could be combined to derive 3D displacement vectors coinciding with the actual movement of a point scatterer (corner cube). The investigations expanded the knowledge regarding the performance and quality of the phase measurements of MIMO-SAR systems operating in the W-band. Their applicability for SHM has been demonstrated on two engineering structures. The results indicate that the MIMO-SAR technology could supplement or even replace classical geodetic and other measurement systems used for deformation monitoring., Aufgrund von Umweltbedingungen und äußeren Kräften welche auf Brücken, Hochhäuser und andere Bauwerke einwirken, verschlechtert sich deren Zustand mit der Zeit. Das Structural Health Monitoring (SHM) zielt darauf ab, potenzielle Schäden welche die Systemintegrität beeinflussen, frühzeitig zu erkennen und zu lokalisieren. Die Identifizierung kann zur Kostensenkung beitragen, indem sie eine rechtzeitige Instandhaltung einleitet und die Lebensdauer des Bauwerks verlängert. Ingenieure verwenden hierzu verschiedene Arten von Sensoren (z.B. Beschleunigungsmesser, Dehnungsmessstreifen usw.), um den Zustand des Bauwerks zu beurteilen. Die meisten Systeme liefern Zeitreihen von Beobachtungen für den Standort des Sensors. Die Erfassung großer Strukturen würde die kostspielige Installation mehrerer Sensoren und die Verkabelung eines Netzwerks für das Erfassungsmanagement erfordern. MIMO-SAR-Systeme, kurz für Multiple Input Multiple Output Synthetic Aperture Radar, sind eine neu aufkommende Alternative. Durch die Aussendung einer frequenzmodulierten Dauerstrichwelle (eng. frequency modulated continuous wave, FMCW) können solche Systeme die terrestrische Radarinterferometrie (TRI) nutzen, um die Bewegung eines Objekts mit hoher zeitlicher und räumlicher Auflösung zu messen. Allerdings sind die Leistungsmerkmale von MIMO-SAR-Systemen für praktische Anwendungen noch nicht ausreichend bekannt. In dieser Arbeit wurde die Anwendbarkeit von W-Band MIMO-SAR für SHM untersucht. Insbesondere wurden die Auswirkungen von unterschiedlichen Einflussfaktoren auf die Genauigkeit eines kommerziellen, kostengünstigen und für Automobilanwendungen entwickelten MIMO-SAR-Systems untersucht. Hierzu wurden in Innen- und Außenbereichen Experimente unter widrigen Wetterbedingungen durchgeführt. Konkret wurden die Auswirkungen von Messrauschen, kurzfristigen Drifts aufgrund von Taktinstabilitäten, meteorologischen Schwankungen und elektromagnetischen Störungen auf die Verschiebungsmessungen analysiert und quantifiziert. Anschließend wurde Anwendbarkeit eines MIMO-SAR-Systems in realistischen Anwendungen, d.h. die Verformung einer Eisenbahnbrücke unter Verkehrslast sowie einer Windkraftanlage unter Arbeitslast, beurteilt. Abgerundet wurde die Untersuchung durch die Entwicklung von Algorithmen zur Ableitung von 3D-Verschiebungsvektoren aus Sätzen von Sichtlinienverschiebungen (eng. Line-of-Sight displacements), wie sie durch TRI gegeben sind. Diese Algorithmen beinhalteten Ausgleichrechnungen nach dem Prinzip der kleinsten Quadrate welche die räumlichen oder zeitlichen Zusammenhänge der Beobachtungen berücksichtigten. Die Ergebnisse zeigen, dass W-Band MIMO-SAR-Sensoren zur Messung kurzfristiger Sichtlinienverschiebungen mit geringen Unsicherheiten (wenigen zehn Mikrometern) und hoher zeitlicher Auflösung (Millisekunden) verwendet werden können. Die in dieser Untersuchung verwendete Systemkonfiguration ermöglichte die 2D-Kartierung der Verschiebungen von Objekten, die sich bis zu 175 Meter entfernt befanden. Dies konnte mit einer hohen Winkel- (ca. 1.4 Grad) und Distanzauflösung (bis zu 4 Zentimetern) realisiert werden. Darüber hinaus konnten die Messungen von drei gleichzeitig arbeitenden MIMO-SAR-Sensoren kombiniert werden, um 3D-Verschiebungsvektoren abzuleiten, die mit der tatsächlichen Bewegung eines Punktstreuers (metallischer Eckwürfel) übereinstimmen. Die Untersuchungen haben das Wissen über die Eigenschaft und Qualität der Phasenmessungen von MIMO-SAR-System, welche im W-Band operieren, erweitert. Deren Anwendbarkeit für SHM wurde dabei an zwei Bauwerken aufgezeigt. Die Ergebnisse weisen darauf hin, dass die MIMO-SAR-Technologie klassische geodätische und andere Messsysteme, die bei Deformationsüberwachung eingesetzt werden, in Zukunft ergänzen oder sogar ersetzen könnte., En raison de leur exposition constante aux conditions environnementales et aux forces extérieures, les ouvrages tels que les ponts, les grands immeubles et autres se détériorent avec le temps. La surveillance de l'état des structures (SHM) vise à identifier et à localiser les dommages potentiels qui pourraient entraîner une modification de l'intégrité du système. L'identification peut contribuer à réduire les coûts en déclenchant une maintenance ciblée et en prolongeant la durée de vie de la structure. Les ingénieurs utilisent différents types de capteurs (par exemple, des accéléromètres, des jauges de contrainte, etc.) pour évaluer l'état de la structure. La plupart des systèmes fournissent une série temporelle d'observations à l'emplacement du capteur. La couverture de grandes structures nécessiterait l'installation coûteuse de plusieurs capteurs et le câblage d'un réseau pour la gestion des acquisitions. Les systèmes MIMO-SAR, abréviation de Multiple Input Multiple Output Synthetic Aperture Radar, constituent une alternative émergente. En émettant une onde continue modulée en fréquence (FMCW), ces systèmes peuvent utiliser l'interférométrie radar terrestre (TRI) pour mesurer avec une grande précision les déplacements d'un objet à haute résolution temporelle et spatiale. Cependant, les effets ayant un impact sur les performances des systèmes MIMO-SAR ne sont pas encore bien compris pour les applications pratiques. Dans cette thèse, l'applicabilité des MIMO-SAR en bande W pour les SHM a été étudiée. Plus précisément, les effets ayant un impact sur la précision d'un système MIMO-SAR commercial et disponible à faible coût pour l'automobile ont été analysés. Des expériences menées dans des environnements intérieurs et extérieurs dans des conditions météorologiques défavorables ont permis d'analyser et de quantifier l'impact du bruit des mesures, des dérives à court terme dues aux instabilités de l'horloge, des variations météorologiques et des interférences électromagnétiques causées par un second système MIMO-SAR actif sur les mesures de déplacement. On a ensuite évalué les capacités d'un système MIMO-SAR pour une application réelle, à savoir la déformation d'un pont de chemin de fer sous la charge du trafic et la déformation d'une tour d'éolienne sous la charge de travail. L'étude a été complétée par le développement d'un algorithme permettant de dériver les vecteurs de déplacement 3D à partir d'un ensemble de déplacements en ligne de visée tels qu'ils sont donnés par TRI. Ces algorithmes ont effectué des ajustements par la méthode des moindres carrés en tenant compte des corrélations spatiales ou temporelles des observations. Les résultats montrent que les capteurs MIMO-SAR en bande W peuvent être utilisés pour mesurer les déplacements en ligne de visée à court terme avec de faibles incertitudes (dizaines de micromètres) et une haute résolution temporelle (millisecondes). La configuration du système utilisée dans cette étude a permis de cartographier en 2D les déplacements d'objets situés jusqu'à 175 mètres avec une haute résolution angulaire (environ. 1.4 degrés) et de distance (jusqu'à 4 centimètres). En outre, les mesures acquises par trois capteurs MIMO-SAR fonctionnant simultanément ont pu être combinées pour dériver des vecteurs de déplacement 3D coïncidant avec le mouvement réel d'un diffuseur ponctuel (cube d'angle). L'enquête a élargi les connaissances concernant la performance et la qualité des mesures de phase des systèmes MIMO-SAR fonctionnant dans la bande W. Leur applicabilité pour la SHM a été démontrée sur deux ouvrages. Les résultats indiquent que la technologie MIMO-SAR pourrait compléter, voire remplacer, les systèmes géodésiques classiques et autres systèmes de mesure utilisés pour la surveillance des déformations., A causa della costante esposizione alle condizioni ambientali e alle forze esterne, le opere civili come ponti, grattacieli e altre si deteriorano nel tempo. Il monitoraggio dello stato di salute delle strutture (Structural Health Monitoring, SHM) mira a identificare e localizzare i potenziali danni che potrebbero causare un'alterazione dell'integrità delle stesse. L'identificazione può contribuire a ridurre i costi rendendo possibile una manutenzione tempestiva e quindi prolungando la durata di una struttura. Gli ingegneri utilizzano vari tipi di sensori (ad esempio accelerometri, estensimetri, ecc.) per valutare le condizioni di una struttura. La maggior parte dei sistemi fornisce una serie temporale di osservazioni raccolte nel luogo dove il sensore è posizionato. I monitoraggi che coprono interamente di grandi strutture richiedono generalmente la costosa installazione di numerosi sensori ed il relativo cablaggio di una rete per gestire la raccolta delle osservazioni. I sistemi MIMO-SAR, acronimo di Multiple Input Multiple Output Synthetic Aperture Radar, sono un'alternativa emergente per queste applicazioni. Emettendo un'onda continua modulata in frequenza (FMCW), questi sistemi possono utilizzare l'interferometria radar terrestre (TRI) per misurare con grande precisione gli spostamenti di un oggetto, con alte risoluzioni temporali e spaziali. Tuttavia, gli effetti che influenzano le prestazioni dei sistemi MIMO-SAR nel loro impiego pratico non sono ancora compresi appieno. In questa tesi è stata studiata l'applicabilità di MIMO-SAR in banda W per SHM. In particolare, sono stati analizzati gli effetti che influenzano l'accuratezza di un sistema MIMO-SAR per il mercato automobilistico, disponibile in commercio a basso costo. Gli esperimenti condotti in ambienti interni ed esterni in condizioni meteorologiche avverse sono stati utilizzati per analizzare e quantificare l'impatto del rumore di misura, delle derive a breve termine dovute all'instabilità dell'orologio, delle variazioni meteorologiche e delle interferenze elettromagnetiche causate da un secondo sistema MIMO-SAR attivo sulle misure di spostamento. A ciò ha fatto seguito la valutazione delle capacità di un sistema MIMO-SAR per un'applicazione reale, ossia la deformazione di un ponte ferroviario sotto il carico del traffico. L'indagine si è conclusa con lo sviluppo di un algoritmo per derivare vettori di spostamento 3D da un insieme di spostamenti misurati lungo differenti linee di vista, misurate grazie alla TRI. I risultati mostrano che i sensori MIMO-SAR in banda W possono essere utilizzati per misurare spostamenti a breve termine lungo la linea di vista con grande accuratezza (decine di micrometri) e alta risoluzione temporale (millisecondi). La configurazione del sistema utilizzata in questa indagine ha permesso la mappatura 2D degli spostamenti di oggetti situati fino ad una distanza di 175 metri con un'alta risoluzione angolare (ca. 1.4 gradi) ed un’alta risoluzione nelle distanze (fino a 4 centimetri). Inoltre, le misure acquisite da tre sensori MIMO-SAR operanti simultaneamente possono essere combinate per ricavare vettori di spostamento 3D che coincidono con l'effettivo movimento di uno scatterer puntiforme (ad esempio, un profilo a forma di triedro retto). L'indagine ha ampliato le conoscenze relative alle prestazioni e alla qualità delle misure di fase dei sistemi MIMO-SAR operanti nella banda W. La loro applicabilità per l'SHM è stata dimostrata su due opere civili. I risultati indicano che la tecnologia MIMO-SAR potrebbe integrare o addirittura sostituire sia sistemi di misura geodetici classici, che sistemi di altro tipo utilizzati per il monitoraggio delle deformazioni.

Published

2023

169. Beach vulnerability assessment at the Island of Hvar

Author

Mićunović, Marin, Rutzinger, Martin, Anders, Katharina, Bremer, Magnus, Eltner, Anette, Höfle, Bernhard, Lindenbergh, Roderik, Mayr, Andreas, Oude Elberink, Sander, Pirotti, Francesco, Scaioni, Marco, Tolksdorf, Hanna, and Zieher, Thomas (Eds.)

Subjects

beach, geomorphology, remote sensing, Adriatic, Hvar

Abstract

Coastal areas are dynamic and complex geomorphological systems often today under strong socioeconomic pressure. One of the most endangered coastal geomorphological forms are beaches. Some recent work shows that 24% of beaches are subject to erosion and 28% of beaches are prograding, while 48% are relatively stable (Luiendijk et al., 2018). Climate change, sea level rise, and increasing anthropogenic pressures make beaches highly vulnerable today. One of the most appropriate methods to calculate and assess their vulnerability is the BVI - Beach Vulnerability Index. The BVI has evolved from the CVI - coastal vulnerability index (Gornitz, 1990) and was developed by Alexandrakis and Poulos (2014). In this work, the vulnerability of beaches on the island of Hvar is assessed by combining different parameters such as beach erosion, morphometric characteristics, land cover change, wave action and anthropogenic impacts at about 40 sites. Different methods are used to analyze each parameter, including method of repeat photography, analysis of archival maps, field work (Fig. 1ab) and remote sensing method using UAV (uncrewed aerial vehicle) and satellite imagery. Remote sensing methods revealed to be very satisfactory for beach geomorphological investigations (Mićunović et al., 2021), therefore the application of remote sensing is further developed in this work. Data collected from the UAV or satellite imagery has been processed in combination with GNSS control points in Drone2Map and Agisoft photogrammetric software (Fig. 1c), and data analyses has also been performed using ESRI ArcGIS Pro software. During my PhD research, data will be collected by UAV several times a year to monitor changes in beach morphology. These results and those calculated by BVI, should contribute to further sustainable coastal management.

Published

2022

170. Effective multi-satellite precipitation fusion procedure conditioned by gauge background fields over the Chinese mainland.

Author

Li, Weiyue, Jiang, Qin, He, Xiaogang, Sun, Haiqing, Sun, Weiwei, Scaioni, Marco, Chen, Sheng, Li, Xin, Gao, Jun, and Hong, Yang

Subjects

*PRECIPITATION gauges, *RAIN gauges, *MULTISENSOR data fusion, *STATISTICAL errors, *REMOTE sensing, *ABSOLUTE value, *GAGES

Abstract

• Limitations of satellite precipitation products can be overcome using data fusion. • We combined gauge-based observation and six satellite products for Chinese Mainland. • Merged product outputs were validated against a range of error metrics. • Our method consistently out-performed individual satellite-based products. • Our method also out-performed other merged precipitation products. The accurate estimation of precipitation has a basis for atmospheric and hydrological applications. However, large uncertainties exist in the estimation of regional precipitation derived solely from remote sensing data. Herein, we develop an effective method to fuse multiple satellite-based precipitation products to capitalize on their strengths and maximize their applicability at the 0.25° resolution scale. Specifically, we describe an approach based on bias correction in individual satellite-based products and their merging with up-scaled (1.0°) gauge-based interpolated data to produce finer -resolution (0.25°) data outputs. By focusing on seven regions to generate the estimates of merged precipitation across the Chinese mainland (MPCM), we performed a full evaluation based on a range of error metrics. The results showed that the bias correction procedure can reduce the discrepancies in the individual satellite-based precipitation products. In addition, the mean absolute error values are also considerably reduced (20%–45%) with respect to the original data over the Chinese mainland. Error statistical metrics demonstrated that the MPCM generated considerably better estimates on a daily scale, and performed better than the satellite-based precipitation products across different precipitation thresholds. The intercomparison results clearly states the superiority of the MPCM against Multi-Source Weighted-Ensemble Precipitation version 2 global product. Nonetheless, we also suggest that the large uncertainties in satellite-based products should be paid more attention over mountainous areas where rain gauge data are insufficient. [ABSTRACT FROM AUTHOR]

Published

2022

171. POINT CLOUD DATASET AND FEM FOR A COMPLEX GEOMETRY: THE SAN LUZI BELL TOWER CASE STUDY

Author

Andreas Wieser, Eugenio Serantoni, Gabriele Bitelli, Ilenia Selvaggi, Brumana, Raffaella, Pracchi, Valeria, Rinaudo, Fluvio, Grimoldi, Alberto, Scaioni, Marco, Previtali, Mattia, Cantini, Lorenzo, Selvaggi I., Bitelli G., Serantoni E., and Wieser A.

Subjects

lcsh:Applied optics. Photonics, Terrestrial laser scanning, Engineering drawing, Computer science, Geomatics, 0211 other engineering and technologies, Point cloud, 02 engineering and technology, lcsh:Technology, Bell tower, Complex geometry, Documentation, 021105 building & construction, 0202 electrical engineering, electronic engineering, information engineering, Structure from motion, lcsh:T, business.industry, lcsh:TA1501-1820, Cultural heritage, Three-dimensional modeling, Finite element model, lcsh:TA1-2040, 020201 artificial intelligence & image processing, lcsh:Engineering (General). Civil engineering (General), business, Tower

Abstract

Detailed three-dimensional reconstruction of heritage objects is crucial for different purposes, such as analysis, preservation and maintenance, among others. Geomatics techniques allow acquiring complex and comprehensive information about geometry and current conditions of the surveyed objects in a short time, which is a great advantage for documentation and historical archives. The reconstruction of three-dimensional models is often performed using either image-based techniques, mainly Close Range Photogrammetry (CRP), including Structure from Motion approaches (SfM), or range-based techniques, such as Terrestrial Laser Scanning (TLS). These approaches have been widely applied in the field of Cultural Heritage to support multidisciplinary studies, from simple documentation to the monitoring of historical buildings, in restoration works or for structural analysis checks. The present paper aims at exploring the potential contribution of Geomatics to Structural Engineering, by investigating capabilities and advantages of TLS for a vertical structure. The experiments presented herein were carried out in a notable case study, the San Luzi church, located in Zuoz (Switzerland) in the Upper Engadin. Its bell tower is about 60 m high and is equipped with four bells. Strong vibrations caused by the ringing of the bells have been observed in the past, and a structural model was desired to enable numerical evaluations of the response of the tower to various load situations by FEM., International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, XLII-2/W11, ISSN:1682-1750, ISSN:2194-9034, ISSN:1682-1777

Published

2019

172. ACCURACY ASSESSMENT OF UNDERWATER PHOTOGRAMMETRIC THREE DIMENSIONAL MODELLING FOR CORAL REEFS

Author

Armin Gruen, Sally J. Holbrook, T. Guo, James L. Hench, Andrew J. Brooks, Matthias Troyer, Alessandro Capra, Russell J. Schmitt, Marco Dubbini, Guo, T., Capra, A., Troyer, M., Gruen, A., Brooks, A. J., Hench, J. L., Schmitt, R. J., Holbrook, S. J., Dubbini, M., Halounova, L., Šafář, V., Remondino, Fabio, Hodač, J., Pavelka, K., Shortis, Mark R., Rinaudo, F., Scaioni, Marco, Boehm, Johannes, and Rieke-Zapp, Dirk H.

Subjects

0106 biological sciences, lcsh:Applied optics. Photonics, Coral reefs, Moorea, Point cloud, Accuracy assessment, Calibration, Coral growth, Photogrammetry, Point clouds, Underwater 3D modelling, 010603 evolutionary biology, 01 natural sciences, lcsh:Technology, Computer vision, Underwater, Remote sensing, Photogrammetry, Underwater 3D Modelling, Accuracy Assessment, Calibration, Point Clouds, Coral Reefs, Coral Growth, Moorea, geography.geographical_feature_category, business.industry, lcsh:T, 010604 marine biology & hydrobiology, Frame (networking), Information Systems, Geography, Planning and Development, lcsh:TA1501-1820, Dimensional modeling, Coral reef, Automation, Geography, lcsh:TA1-2040, Artificial intelligence, business, lcsh:Engineering (General). Civil engineering (General)

Abstract

Recent advances in automation of photogrammetric 3D modelling software packages have stimulated interest in reconstructing highly accurate 3D object geometry in unconventional environments such as underwater utilizing simple and low-cost camera systems. The accuracy of underwater 3D modelling is affected by more parameters than in single media cases. This study is part of a larger project on 3D measurements of temporal change of coral cover in tropical waters. It compares the accuracies of 3D point clouds generated by using images acquired from a system camera mounted in an underwater housing and the popular GoPro cameras respectively. A precisely measured calibration frame was placed in the target scene in order to provide accurate control information and also quantify the errors of the modelling procedure. In addition, several objects (cinder blocks) with various shapes were arranged in the air and underwater and 3D point clouds were generated by automated image matching. These were further used to examine the relative accuracy of the point cloud generation by comparing the point clouds of the individual objects with the objects measured by the system camera in air (the best possible values). Given a working distance of about 1.5 m, the GoPro camera can achieve a relative accuracy of 1.3 mm in air and 2.0 mm in water. The system camera achieved an accuracy of 1.8 mm in water, which meets our requirements for coral measurement in this system., International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, XLI (B5), ISSN:1682-1750, ISSN:2194-9034, ISSN:1682-1777

Published

2018

173. Geoelectrical characterization and monitoring of slopes on a rainfall-triggered landslide simulator.

Author

Hojat, Azadeh, Arosio, Diego, Ivanov, Vladislav Ivov, Longoni, Laura, Papini, Monica, Scaioni, Marco, Tresoldi, Greta, and Zanzi, Luigi

Subjects

*LANDSLIDES, *TIME-domain reflectometry, *ELECTRICAL resistivity

Abstract

In this paper, we present the results of time-lapse electrical resistivity tomography (ERT) monitoring of rainfall-triggered shallow landslides reproduced on a laboratory-scale physical model. The main objective of our experiments was to monitor rainwater infiltration through landslide body in order to improve our understanding of the precursors of failure. Time-domain reflectometry (TDR) data were also acquired to obtain the volumetric water content. Knowing the porosity, water saturation was calculated from the volumetric water content and we could calibrate Archie's equation to calculate water saturation maps from inverted resistivity values. Time-lapse ERT images proved to be effective in monitoring the hydrogeological conditions of the slope as well as in detecting the development of fracture zones before collapse. We performed eight laboratory tests and the results show that the landslide body becomes unstable at zones where the water saturation exceeds 45%. It was also observed that instability could occur at the boundaries between areas with different water saturations. Our study shows that time-lapse ERT technique can be employed to monitor the hydrogeological conditions of landslide bodies and the monitoring strategy could be extended to field-scale applications in areas prone to the development of shallow landslides. • ERT was employed at lab scale to monitor rainfall-triggered shallow landslides. • Time-lapse ERT data could effectively monitor the internal conditions of the slope. • High saturations or saturation gradients can be precursors of potential instability. • Unstable zones were identified as high resistivity areas before slope failure. • Archie's law was calibrated to convert resistivity maps to water saturation maps. [ABSTRACT FROM AUTHOR]

Published

2019

174. Extreme rainfall trends of 21 typical urban areas in China during 1998-2015 based on remotely sensed data sets.

Author

Li W, Zhao M, Scaioni M, Hosseini SR, Wang X, Yao D, Zhang K, Gao J, and Li X

Subjects

Beijing, China, Cities, Climate, Remote Sensing Technology, Rivers, Urbanization, Environmental Monitoring methods, Rain

Abstract

With the increase of population, many cities are growing in size at a phenomenal rate. Urbanization changes the urban underlying surface, influences the micro-climate, and sometimes affects the local precipitation process. In this study, we investigated the trends of extreme rainfall in China's 21 typical urban areas. Based on a series of daily rainfall and "Urban/built-up" dataset from TMPA 3B42 and MCD12Q1 products in China, trends in extreme precipitation, with the threshold defined as 95th (pre95p) and 99th (pre99p) percentiles of annual rain days during 1998-2015, have been assessed in China, and especially in 21 typical urban areas from 1998 to 2015. The tendency curves in extreme rainfall of different years are presented. In this period, more than 66% regions of China covered by TMPA 3B42 have increasing trends in extreme rainfall with pre95p threshold. The 21 typical urban areas showed different trends-in over half of these areas, upward tendencies in extreme rainfall were observed, particularly in Dalian, Beijing, and Chongqing. Seventeen urban areas showed increasing tendencies in pre95p extreme rainfall days, including Shanghai, Nanjing, Hangzhou, and Suzhou in the Yangtze River Delta region. The results also illustrate that southeastern coastal urban areas of China may have experienced decreasing occurrences in extreme rainfall.

Published

2019