Remote Sensing and Radar

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Remote Sensing Laboratory Dept. of Information Engineering and Computer Science University of Trento Via Sommarive, 5, I-38123 Povo, Trento, Italy Master in Telecommunication Engineering: Specialization (Orientamento) Remote Sensing and Radar Coordinator: Lorenzo Bruzzone E-mail: lorenzo.bruzzone@ing.unitn.it Web page: http://rslab.disi.unitn.it

Introduction Rete di Telecom Commerciale Crosslink Ottico Ka Crosslink Crosslink Ottico Sensore multispettrale Sistema radar Ka Ka Ka Sensore Iperspettrale Comm Gateway Stazione di Ricezione Utente Sito di Fusione Dati, Elaborazioe e Archiviazione Elaborazione Locale RSLab Lorenzo Bruzzone 2

Skills and Know-How Design of advanced remote sensing systems (active and passive systems; satellite, airborne, UAV, and terrestrial systems). Design advanced active systems (radar, lidar, sonar) for different applications (air traffic control, environmental monitoring, meteo nowcast and forecast, sea monitoring, biomedical, etc.). Design of integrated communication systems (remote sensing, radar, GIS, radiolocalization, etc.) for surveillance, detection and environmental monitoring. Design of satellites systems and their use in Earth observation, telecommunication and planetary exploration. Design of multiplatform systems (satellites UAV, airplanes, sensor networks) for telecommunications. RSLab Lorenzo Bruzzone 3

Skills and Know-How Detailed knowledge of technologies related to satellite radiolocalization (e.g., GPS). Basic knowledge of the GIS (Geographic Information Systems) technology. Design of advanced environmental monitoring systems that integrate different technologies of telecommunications. Design of multidimensional signal processing, image processing and pattern recognition methods and algorithms. Systems and methodologies for the analysis of Big Data. Techniques for 3D modeling and multidimensional visualization. Design of multisensor data analysis systems and of data fusion methodologies. RSLab Lorenzo Bruzzone 4

Application Domains Environmental Monitoring Climate change Urban planning Big Data Water reservoir Resource Exploration Automotive Image Time Series Biomedical Air Traffic Control Smart cities Stratigraphy Monitoring Urban Areas Damage Assessment Civil protection Snow and Ice Detection and Estimation Forest management Emergency Response Risk Assessment Imaging Planetary Exploration Earth Observation Precision Farming Surveillance and Infrastructure monitoring Meteorology Food Agriculture Heat fluxes RSLab Lorenzo Bruzzone 5

Courses The specialization take specific advantage from the background given by the mandatory courses on Digital Signal Processing and Recognition Systems. The full path of the specialization includes the following optional courses: Sistemi di Telerilevamento (Remote Sensing Systems) (6 cdt, II semester, every year); Advanced Remote Sensing Systems for Environment (6 cdt, I semester A.A. 2015-2016); Radar and Radiolocalization (6 cdt, I semester A.A. 2014-2015). More information on the optional courses is provided in the next slides with the purpose to allow the students to make a proper choice. RSLab Lorenzo Bruzzone 6

Sistemi di Telerilevamento (6 cdt) General Concepts Introduction to remote sensing systems Radiation theory Sun and Earth emission properties Atmospheric windows Spectral regions used in remote sensing Spectral signature Architecture of remote sensing systems RSLab Lorenzo Bruzzone 7

Sistemi di Telerilevamento (6 cdt) Acquisition Process Remote sensing platforms; Satellites for telecommunication and remote sensing; Ground segment and space segment; Passive and active sensors for remote sensing; Multispectral and hyperspectral sensors; Radar imaging sensors; Geometrical and spectral resolution; Acquisition architectures; Main satellite missions for remote sensing. RSLab Lorenzo Bruzzone 8

Sistemi di Telerilevamento (6 cdt) Remote Sensing Image Analysis Basics on multidimensional image processing; Radiometric and geometric distortions and corrections; Image registration; Image filtering; Segmentation and texture extraction; Multispectral and hyperspectral image processing; Radar image processing. RSLab Lorenzo Bruzzone 9

Sistemi di Telerilevamento (6 cdt) Automatic data recognition Architecture of automatic recognition systems; Pre-processing and feature extraction; Discriminant functions and machine learning; Automatic classification techniques: Statistical approaches; Artificial neural networks; Support vector machines; Change detection techniques. RSLab Lorenzo Bruzzone 10

Remote sensing applications Sistemi di Telerilevamento (6 cdt) Environmental monitoring Risk assessment and civil protection Resource monitoring Agriculture (shift of cultivation, production estimation, etc.) Meteorology (atmosphere dynamic, weather forecast, estimation of precipitations intensity, etc.) Thematic map production Planetary exploration RSLab Lorenzo Bruzzone 11

Advanced Remote Sensing Systems for Environment (6 cdt) Remote sensing and situ sensing; UAV remote sensing systems; Payloads for UAV systems; Planning of acquisitions with UAV systems; Integrated Earth observation; Data fusion and data assimilation. RSLab Lorenzo Bruzzone 12

Advanced Remote Sensing Systems for Environment (6 cdt) Advanced approaches for the design of satellite missions: Basics of space environment; Analysis of mission constraints; Architecture of a satellite system; Risk analysis. RSLab Lorenzo Bruzzone 13

Advanced Remote Sensing Systems for Environment (6 cdt) Orbital mechanics; Power, structural and thermal design; Propulsion; Case study (example of real missions studied in detail). RSLab Lorenzo Bruzzone 14

Advanced Remote Sensing Systems for Environment (6 cdt) Geographical reference systems, ellipsoid of reference, and standards. GPS and Differential GPS. Basics of geographical information systems. Basics of data representation and 3-dimensional visualization. RSLab Lorenzo Bruzzone 15

NDVI NDVI Advanced Remote Sensing Systems for Environment (6 cdt) Analysis of multitemporal optical and SAR images; Analysis of time series of data; Multiscale image processing; Multisensor architectures. 200 180 160 140 120 100 Loss of vegetation 1989 1997-1.0 0 +1.0 200 180 160 140 120 100 Re-vegetation RSLab Lorenzo Bruzzone 16

Advanced Remote Sensing Systems for Environment (6 cdt) 3D acquisition with Synthetic Aperture Radar (SAR); SAR Interferometry; Differential interferometry; Persistent scatters; SAR tomography. R 1 R 2 RSLab Lorenzo Bruzzone 17

Advanced Remote Sensing Systems for Environment (6 cdt) RSLab Lorenzo Bruzzone 18

Advanced Remote Sensing Systems for Environment (6 cdt) RSLab Lorenzo Bruzzone 19

Advanced Remote Sensing Systems for Environment (6 cdt) Design of systems for: Environmental Monitoring (i.e. forestry, agriculture, glaciers, climate change, etc.); Civil protection (risk monitoring and damage assessment landslides, subsidence, forest fires, floods, earthquake, etc.); for Infrastructure monitoring (e.g. buildings, bridges, man-made structures, etc.); Surveillance at detailed scale (e.g. industrial areas, ports, airports, etc.). RSLab Lorenzo Bruzzone 20

Advanced Remote Sensing Systems for Environment (6 cdt) Integrated multisensor and multisource civil protection system (forest fires). RSLab Lorenzo Bruzzone 21

Advanced Remote Sensing Systems for Environment (6 cdt) Example: Images acquired before (5th April 2009) and after (12th September 2009) the earthquake of L Aquila (Italy, 6th April 2009). 1m 1m resolution X-band 1-look Amplitude HH-polarization 57-58 degree incidence angle Ascending orbit Right look CSKS1 Calibrated Co-registered Geo-referred Optical image5thgeoeye, Tele Atlas 2011 April 2009 Google th September RGB 12 multitemporal composition 2009 Backscattering decrease Backscattering increase COSMO-SkyMed Product ASI Agenzia Spaziale Italiana (2009). All Rights Reserved. RSLab Lorenzo Bruzzone Unchanged areas 22

Optical image Pictometry International Corp Microsoft Corporation Advanced Remote Sensing Systems for Environment (6 cdt) Pre-Crisis Reference Image Post-Crisis Reference Image Destroyed Building Change (no destroyed building) RSLab Lorenzo Bruzzone 23

Radar and Radiolocalization (6 cdt) Side lobe energy Radar System Introduction to active systems; Basic concepts; Illumination sources, signals, applications; Taxonomy of active systems; Examples of active systems. Altitude return Basics of microwave active systems; Surveillance radar systems; Radar tracking; Doppler radar; Radar signal processing RSLab Lorenzo Bruzzone 24

Radar and Radiolocalization (6 cdt) Radar Systems for Civil Air Traffic Control Architecture of a system for civil air traffic control; Interaction between primary and secondary radar; Transponders; Communication via secondary radars; Radar standards. RSLab Lorenzo Bruzzone 25

Radar and Radiolocalization (6 cdt) Meteorological Radar Meteorological radar; Reflectivity targets; Equation of meteo radar; Polarimetric radar; Metorological signals; Analysis of meteorological signals. RSLab Lorenzo Bruzzone 26

Radar and Radiolocalization (6 cdt) Ground Penetrating Radar and Radar Sounder Architecture of the system; Georadar; Low frequency radar sounders; Applications (geology and ice monitoring, planetary exploration, pipeline detection, etc.). RSLab Lorenzo Bruzzone 27

Radar and Radiolocalization (6 cdt) Ultra-Wide Band (UWB) Radar Radar UWB technology; Radar UWB anticollision (e.g. automotive); RSLab Lorenzo Bruzzone 28

Radar and Radiolocalization (6 cdt) Lidar systems Basics on optical active systems; Basic concepts; Equations and architecture; Lidar for atmosphere monitoring; Lidar for land monitoring; Lidar for speed control (e.g. autovelox). RSLab Lorenzo Bruzzone 29

Radar and Radiolocalization (6 cdt) 15 July 2001 15 September 2001 RSLab Lorenzo Bruzzone 30

Radar and Radiolocalization (6 cdt) Sonar and Sidescan Sonar Basics of acoustic active systems; Array and beam pattern; Sonar signals; Noise in sonar systems and sonar equation; Sidescan sonar; Application of sonar. RSLab Lorenzo Bruzzone 31

Radar and Radiolocalization (6 cdt) Ecographic and Eco-Doppler systems Basics on ultrasonic systems; Equations and architecture; Acoustic propagation in tissues; Ultrasound signal processing; Applications. RSLab Lorenzo Bruzzone 32

Remote Sensing Laboratory Staff Prof. Lorenzo Bruzzone (Director) Dr. Francesca Bovolo Dr. Begüm Demir Dr. Claudio Persello Dr. Youkyung Han Main External Collaborators Ing. Nicola Falco Dr. Jeff Plaut (JPL Caltech - NASA) Ing. Ana-Maria Ilisei Prof. Marcello Coradini (European Space Agency) Ing. Sicong Liu Dr. Pierre Soille (Joint Research Centre EU) Ing. Carlo Marin Prof. Jon Atli Benediktsson (University of Iceland) Ing. Davide Castelletti Prof. Gustavo Camps-Valls (University of Valecia) Ing. Claudia Paris Prof. Subhasis Chaudhuri (IIT, Bombay) Ing. Silvia Demetri Dr. Paolo Pasquali (SARMAP, Svizzera) Dott. Massimo Zanetti Dr. Diego Fernandez Prieto (European Space Agency) Dott. Tatiana Solano Correa Dr. Roberto Cossu (European Space Agency) RSLab Lorenzo Bruzzone 33

More Information @... RSLab Lorenzo Bruzzone 34