Space-Based Earth Observations for Disaster Risk Management

Cozannet, Gonéri Le; Kervyn, Matthieu; Russo, Simone; Speranza, Chinwe Ifejika; Ferrier, Pierric; Foumelis, Michael; Lopez, Téodolina; Modaressi, Hormoz

doi:10.1007/s10712-020-09586-5

Cited by 55 publications

(34 citation statements)

References 141 publications

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“…It is important to note that the above represents an optimum situation and delays due to image acquisition may vary ending up in reduced response from EO (up to three days). Nevertheless, this is not related to our current capacity to access and process the data practically in real time (Le Cozannet et al 2020 ).…”

Section: Resultsmentioning

confidence: 98%

On rapid multidisciplinary response aspects for Samos 2020 M7.0 earthquake

et al. 2021

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Following the M 7.0 earthquake that struck the Greek island of Samos and Turkey's western coast, causing extensive damage and casualties, we combined existing knowledge geodatabases concerning historical seismicity and rupture zones with seismological and geodetic measurements as well as with modelling and in situ observations, to provide an assessment of rapid response to the seismic event. In this paper, we demonstrate that in the frame of the gradual provision of information from the individual scientific disciplines, taking into account their respective potential and limitations, a multidisciplinary approach is able to address more efficiently rapid response issues in order to allow effective preliminary interpretation of the earthquake activity, even within the first 24 h of the event. It focuses on the assessment of the timely provision of information by each discipline, evaluating the access to primary data sources as well as the maturity of the techniques in terms of accuracy and rapid data processing. Within a period of less than a week, several constraints were partially compensated for, allowing the delivery of more robust results and interpretation. The study highlights the readiness level of the various domains that has been significantly improved over the past years, including rapid seismological solutions, systematic availability of free and open Earth Observation data and on-demand online processing through dedicated platforms. Their combination with routinely applied inversion modelling and timely in situ observation is leading to improved operational response levels. Supplementary Information The online version contains supplementary material available at 10.1007/s11600-021-00578-6.

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Section: Resultsmentioning

confidence: 98%

On rapid multidisciplinary response aspects for Samos 2020 M7.0 earthquake

et al. 2021

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“…Improvements in the resolution of earth observation imagery also allow relevant information to be derived for assessing the vulnerability of exposed assets. Satellite imagery has sufficient resolution to provide basic structural characteristics (building shape, materials) that can be complemented by other survey methods including sample visits to provide assessments of structural vulnerability to different types of hazards (Le Cozannet et al 2020). For example, one assessment of structural vulnerability to earthquakes in Padang (Indonesia) found that a model using satellite imagery verified by sample site visits was able to provide a catalogue of municipal building vulnerability with fairly high accuracy (error rate of 10%) (Geiß, Klotz, and Taubenböck 2014).…”

Section: Vulnerabilitymentioning

confidence: 99%

“…A comprehensive assessment of vulnerability to hazards should also account for other factors beyond the structural vulnerability of buildings or infrastructure. Earth observations of nighttime light intensity can provide useful information on local population levels (Le Cozannet et al 2020). Big data analytical techniques such as machine learning and deep learning have been successfully used to analyze earth observation and street-level imagery to identify indicators of poverty and well-being in regions in Africa and India not wellcovered by census data (Lee et al 2020;Yeh et al 2020).…”

Section: Vulnerabilitymentioning

confidence: 99%

Leveraging Technology and Innovation for Disaster Risk Management and Financing

2020

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“…Although of importance, coastal hazards related to ice (e.g., for navigation safety on sea-ice or ice-infested coastal waters, permafrost thaw, etc.) and plastic pollution (Viatte et al 2020) are left out of this review, and so do the aspects related to the assessment of exposure and vulnerability, such as urbanisation and land management practices (Le Cozannet et al 2020). Current gaps and perspectives or recommendations on using EO for a reliable evaluation and prediction of coastal hazards are discussed in the final section.…”

Section: Introductionmentioning

confidence: 99%

Earth Observations for Monitoring Marine Coastal Hazards and Their Drivers

et al. 2020

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Coastal zones have large social, economic and environmental values. They are more densely populated than the hinterland and concentrate large economic assets, critical infrastructures and human activities such as tourism, fisheries, navigation. Furthermore, coastal oceans are home to a wealth of living marine resources and very productive ecosystems. Yet, coastal zones are exposed to various natural and anthropogenic hazards. To reduce the risks associated with marine hazards, sustained coastal zone monitoring programs, forecasting and early warning systems are increasingly needed. Earth observations (EO), and in particular satellite remote sensing, provide invaluable information: satellite-borne sensors allow an effective monitoring of the quasi-global ocean, with synoptic views of large areas, good spatial and temporal resolution, and sustained time-series covering several years to decades. However, satellite observations do not always meet the precision required by users, in particular in dynamic coastal zones, characterized by shorter-scale variability. A variety of sensors are used to directly monitor the coastal zone and their observations can also be integrated into numerical models to provide a full 4D monitoring of the ocean and forecasts. Here, we review how EO, and more particularly satellite observations, can monitor coastal hazards and their drivers. These include coastal flooding, shoreline changes, maritime security, marine pollution, water quality, and marine ecology shifts on the one hand, and several physical characteristics (bathymetry, topography, vertical land motion) of coastal zones, meteorological and oceanic (metocean) variables that can act as forcing factors for coastal hazards on the other hand.

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Space-Based Earth Observations for Disaster Risk Management

Cited by 55 publications

References 141 publications

On rapid multidisciplinary response aspects for Samos 2020 M7.0 earthquake

On rapid multidisciplinary response aspects for Samos 2020 M7.0 earthquake

Leveraging Technology and Innovation for Disaster Risk Management and Financing

Earth Observations for Monitoring Marine Coastal Hazards and Their Drivers

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