SBAS-DInSAR processing on the ESA Geohazards Exploitation PlatformEmmanuel Mathot
In the context of space-borne geodetic techniques, Differential Synthetic Aperture Radar Interferometry (DInSAR) has demonstrated its high performance in measuring surface displacements in different conditions and scenarios, both natural and anthropic. In particular, the advanced DInSAR time series processing method referred to as Small BAseline Subset (SBAS), that allows studying both the spatial and temporal variability of the surface displacements, has proven to be particularly suitable in different contexts, as for natural hazards (volcanoes, earthquakes and landslides) and human-induced deformation (subsidence due to aquifer exploitation, mining operations, and building of large infrastructures). Recently, an efficient implementation of this algorithm (referred to as P-SBAS approach) has been fully integrated within the ESA’s Grid Processing on Demand (G-POD) environment, which is part of the [Geohazards Thematic Exploitation Platform (GEP)](https://geohazards-tep.eo.esa.int/#!) of ESA. The GEP is devoted to the exploitation of EO data resources in the context of the Geohazard Supersites & Natural Laboratories as well as on the CEOS Pilots on Seismic Hazards and Volcanoes. The GEP is sourced with elements, data and processing, including P-SBAS, relevant to the geohazards theme. The integration of the P-SBAS algorithm within GEP resulted in a web-based tool freely available to the scientific community. This tool allows users to process, from their own laptops, the European SAR data archives (ERS, ENVISAT and Sentinel-1) for obtaining surface displacement maps and time series in a completely unsupervised way, without caring about data download and processing facility procurements. The workshop is organized in four parts. First, a short overview on the DInSAR processing methods allowing retrieving mean surface deformation maps and displacement time series will be provided, with a specific focus on the SBAS-DInSAR technique. Secondly, the GEP and G-POD environments will be introduced and the P-SBAS web tool will be presented. The third and the fourth parts are dedicated to the advanced features and to case studies and results achieved via the web tool, respectively.
This presentation was made for my 2nd year 2nd term course.
Me and my friend gave this presentation.
We are very much interested in cosmology and space program.
**If you want the script of this presentation leave a message in LinkedIn
DSD-SEA 2018 Coupling of Hydrodynamic and Wave Models for Predicting Coastal ...Deltares
Presentation by Mr. Andri Ramdhani (Indonesian Agency for Meteorology, Climatology, and Geophysics) at the Seminar Cutting Edge Hydro Software for South-East Asia, during the Deltares Software Days South-East Asia 2018. Thursday, 6 September 2018, Yogyakarta.
SBAS-DInSAR processing on the ESA Geohazards Exploitation PlatformEmmanuel Mathot
In the context of space-borne geodetic techniques, Differential Synthetic Aperture Radar Interferometry (DInSAR) has demonstrated its high performance in measuring surface displacements in different conditions and scenarios, both natural and anthropic. In particular, the advanced DInSAR time series processing method referred to as Small BAseline Subset (SBAS), that allows studying both the spatial and temporal variability of the surface displacements, has proven to be particularly suitable in different contexts, as for natural hazards (volcanoes, earthquakes and landslides) and human-induced deformation (subsidence due to aquifer exploitation, mining operations, and building of large infrastructures). Recently, an efficient implementation of this algorithm (referred to as P-SBAS approach) has been fully integrated within the ESA’s Grid Processing on Demand (G-POD) environment, which is part of the [Geohazards Thematic Exploitation Platform (GEP)](https://geohazards-tep.eo.esa.int/#!) of ESA. The GEP is devoted to the exploitation of EO data resources in the context of the Geohazard Supersites & Natural Laboratories as well as on the CEOS Pilots on Seismic Hazards and Volcanoes. The GEP is sourced with elements, data and processing, including P-SBAS, relevant to the geohazards theme. The integration of the P-SBAS algorithm within GEP resulted in a web-based tool freely available to the scientific community. This tool allows users to process, from their own laptops, the European SAR data archives (ERS, ENVISAT and Sentinel-1) for obtaining surface displacement maps and time series in a completely unsupervised way, without caring about data download and processing facility procurements. The workshop is organized in four parts. First, a short overview on the DInSAR processing methods allowing retrieving mean surface deformation maps and displacement time series will be provided, with a specific focus on the SBAS-DInSAR technique. Secondly, the GEP and G-POD environments will be introduced and the P-SBAS web tool will be presented. The third and the fourth parts are dedicated to the advanced features and to case studies and results achieved via the web tool, respectively.
This presentation was made for my 2nd year 2nd term course.
Me and my friend gave this presentation.
We are very much interested in cosmology and space program.
**If you want the script of this presentation leave a message in LinkedIn
DSD-SEA 2018 Coupling of Hydrodynamic and Wave Models for Predicting Coastal ...Deltares
Presentation by Mr. Andri Ramdhani (Indonesian Agency for Meteorology, Climatology, and Geophysics) at the Seminar Cutting Edge Hydro Software for South-East Asia, during the Deltares Software Days South-East Asia 2018. Thursday, 6 September 2018, Yogyakarta.
How to better understand SAR, interpret SAR products and realize the limitationsNopphawanTamkuan
This content shows how to better understand SAR (how to interpret SAR images and read SAR interferogram ). Moreover, capacities and limitations of SAR are discussed for each disaster emergency mapping (Flood, Landslide and Earthquake).
Electronic Warfare Training Crash Course by TONEX
Electronic Warfare Training Crash Course sets up Electronic Warfare (EW) establishment intended for examiners, engineers, electrical specialists, venture directors, electronic warfare specialized experts who outline or work radar frameworks and electronic warfare frameworks; and anybody engaged with arranging, plan, investigation, reenactment, prerequisites definition, execution detail, obtainment, test, security and assessment of electronic assault hardware.
Electronic Warfare Training Crash Course depicts military activity including the utilization of electromagnetic (EM) and coordinated vitality (DE) to control the EMS or to assault the adversary. TONEX has been a pioneer in electronic warfare preparing administrations since 1992.
#Who Should Attend Electronic Warfare Course
Technical personnel
Electronic warfare or radar system planning, design, development, operations and maintenance
Electrical engineers
Software engineers
System engineers
System analysts
Cyber security professionals
Verification and validation personnel
Project managers
Program managers
#Learning Objectives
Endless supply of Electronic Warfare Training Crash Course, the participants can:
Rundown premise of Electronic Warfare (EW) ideas, engineering and methods
Investigate the utilization of electronic warfare ideas to ground, airborne and maritime surface warfare
Depict the key ideas of electromagnetic field hypothesis
Depict prorogation models, correspondence block and sticking execution expectation
Outline observable pathway (LOS), two-beam, and blade edge diffraction engendering models
Comprehend the essentials of radars and radar cross area
Portray EW and surveillance beneficiary framework configuration exchange off
Give cases of Directed vitality weapons and stealth
Depict how hunt and following radars work
Rundown the utilitarian and operational susceptibilities of weapon frameworks to electronic warfare
Comprehend Electronic Warfare Systems Engineering and System of Systems Engineering (SoSE) standards
Comprehend the application displaying, reproduction and net-driven engineering to electronic warfare.
#Course Agenda
What is Electronic Warfare (EW)?
Electronic Warfare principles
Overview of signals such as radio, infrared or radar
Electronic Warfare architecture
Naval EW
Ground EW
Airborne EW
Cyber EW
RF electronic warfare
Infrared Countermeasures
Visit Tonex website for more information about this course
https://www.tonex.com/training-courses/electronic-warfare-training-crash-course/
How to better understand SAR, interpret SAR products and realize the limitationsNopphawanTamkuan
This content shows how to better understand SAR (how to interpret SAR images and read SAR interferogram ). Moreover, capacities and limitations of SAR are discussed for each disaster emergency mapping (Flood, Landslide and Earthquake).
Electronic Warfare Training Crash Course by TONEX
Electronic Warfare Training Crash Course sets up Electronic Warfare (EW) establishment intended for examiners, engineers, electrical specialists, venture directors, electronic warfare specialized experts who outline or work radar frameworks and electronic warfare frameworks; and anybody engaged with arranging, plan, investigation, reenactment, prerequisites definition, execution detail, obtainment, test, security and assessment of electronic assault hardware.
Electronic Warfare Training Crash Course depicts military activity including the utilization of electromagnetic (EM) and coordinated vitality (DE) to control the EMS or to assault the adversary. TONEX has been a pioneer in electronic warfare preparing administrations since 1992.
#Who Should Attend Electronic Warfare Course
Technical personnel
Electronic warfare or radar system planning, design, development, operations and maintenance
Electrical engineers
Software engineers
System engineers
System analysts
Cyber security professionals
Verification and validation personnel
Project managers
Program managers
#Learning Objectives
Endless supply of Electronic Warfare Training Crash Course, the participants can:
Rundown premise of Electronic Warfare (EW) ideas, engineering and methods
Investigate the utilization of electronic warfare ideas to ground, airborne and maritime surface warfare
Depict the key ideas of electromagnetic field hypothesis
Depict prorogation models, correspondence block and sticking execution expectation
Outline observable pathway (LOS), two-beam, and blade edge diffraction engendering models
Comprehend the essentials of radars and radar cross area
Portray EW and surveillance beneficiary framework configuration exchange off
Give cases of Directed vitality weapons and stealth
Depict how hunt and following radars work
Rundown the utilitarian and operational susceptibilities of weapon frameworks to electronic warfare
Comprehend Electronic Warfare Systems Engineering and System of Systems Engineering (SoSE) standards
Comprehend the application displaying, reproduction and net-driven engineering to electronic warfare.
#Course Agenda
What is Electronic Warfare (EW)?
Electronic Warfare principles
Overview of signals such as radio, infrared or radar
Electronic Warfare architecture
Naval EW
Ground EW
Airborne EW
Cyber EW
RF electronic warfare
Infrared Countermeasures
Visit Tonex website for more information about this course
https://www.tonex.com/training-courses/electronic-warfare-training-crash-course/
23. ReceiverFlight Controller
ppm signal
pwm signal
Raspberry Pi 3
3D Camera
ReceiverFlight Controller
ppm signal
pwm signal
Raspberry Pi 3
3D Camera
Customize Drone Component
FB : โดรนประกอบ สอนทําโดรน By Mac