Exposure Estimation from Multi-Resolution Optical Satellite Imagery for Seismic Risk Assessment

Wieland, Marc; Pittore, Massimiliano; Parolai, Stefano; Zschau, Jochen

doi:10.3390/ijgi1010069

Cited by 30 publications

(39 citation statements)

References 20 publications

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“…In a tier 2 analysis, freeof-cost medium-resolution satellite images are analyzed to outline the extent of built-up areas and to delineate them into areas of relatively homogeneous urban structure at an aggregated neighborhood scale. The tier 2 analysis provides a detailed processing mask for exposure (Wieland et al, 2012a), and the resulting zonation concurs to define the spatial base layer for a stratified sampling to optimize in situ data capturing at the most detailed per-building scale. In a tier 3 analysis, per-building data is acquired and integrated using standard rapid visual screening (RVS; Federal Emergency Management Agency [FEMA] 154, 2002), novel remote rapid visual screening (RRVS) from omnidirectional camera images (Wieland, Pittore, Parolai, Zschau, Moldobekov, et al, 2012) and high-resolution satellite image analysis (Wieland et al, 2012b).…”

Section: Methodsmentioning

confidence: 99%

“…In successive stages of zonation, the image pixels are clustered and labeled depending on their approximate construction date and predominant building types using change-detection analysis and machine learning assisted image analysis. The zonation steps are explained in detail in Wieland et al (2012a). Complementary information about parameter tuning and training of image analysis algorithms along with a performance evaluation of different machine learning classifiers that were used for the urban pattern recognition is given in Wieland and Pittore (2014).…”

Section: Emca Building Typologymentioning

confidence: 99%

“…Omnidirectional images have been acquired for the cities of Bishkek (Kyrgyzstan; Wieland et al, 2012a), Osh (Kyrgyz-stan), Jalalabad (Kyrgyzstan), Dushanbe (Tajikistan; Pilz et al, 2013), and Khorog (Tajikistan). Field surveys are easy to perform, and operators do not necessarily have to be skilled engineers because the screening of building is carried out at a later stage by analyzing the captured images.…”

Section: Omnidirectional Imaging and Rrvs Surveysmentioning

confidence: 99%

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A Multiscale Exposure Model for Seismic Risk Assessment in Central Asia

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Section: Methodsmentioning

confidence: 99%

Section: Emca Building Typologymentioning

confidence: 99%

Section: Omnidirectional Imaging and Rrvs Surveysmentioning

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See 1 more Smart Citation

A Multiscale Exposure Model for Seismic Risk Assessment in Central Asia

Wieland

Pittore

Parolai

et al. 2014

Seismological Research Letters

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“…To improve accuracy, a great deal of post-processing work must be performed. For a large number of buildings, applying these automatic or semiautomatic procedures is more difficult, and sometimes, even impossible (Aytekin et al 2009;Durieux et al 2008;Pittore and Wieland 2013;Su et al 2015;Wieland et al 2012). The GE images we used have only red, green, and blue bands, i.e., their spectral information is much poorer than that of commercial ones, thereby aggravating such difficulties.…”

Section: Estimating Building Footprint Areas From Ge Imagesmentioning

confidence: 99%

“…There are generally three major types of methods for analyzing seismic exposures, vulnerabilities, and risks: (1) the conventional and mainstream loss ratio curve (LRC) and/ or damaged probability matrix (DPM)-based methods (e.g., ATC 1985;FEMA 1999;Grünthal 1998;Inel et al 2008;Ploeger et al 2010), (2) exposure and vulnerability (E and V) or vulnerability (V) composite index-focused methods (e.g., Carreño et al 2007;Cutter et al 2003;Cutter and Finch 2008;Su et al 2007), and (3) remote sensing (RS)-based E and/or V methods (e.g., Ehrlich et al 2010Geiß et al 2014Geiß et al , 2015Geiß et al , 2016Pittore and Wieland 2013;Taubenböck et al 2009;Wieland et al 2012) (for more, please see Table 1). The conventional LRC and/or DPM-based methods can yield definite and accurate exposure, vulnerability, and risk results.…”

Section: Introductionmentioning

confidence: 99%

“Internet+” approach to mapping exposure and seismic vulnerability of buildings in a context of rapid socioeconomic growth: a case study in Tangshan, China

Sun

et al. 2016

Nat Hazards

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This paper presents the development of an ''Internet?'' approach to mapping exposure and seismic vulnerability of buildings in a context of rapid socioeconomic growth. This approach is a combination of the following interdependent components: (1) extraction of footprint areas of a large number of buildings from high-resolution Google Earth images; (2) estimation of floor numbers of these buildings with an integrated use of high-resolution Google Earth images, Tencent/Baidu Street Views, crowdsourcing data, and associated building-relevant local knowledge; and (3) identification of structural types of these buildings by a combined use of crowdsourcing data and associated buildingrelevant local knowledge. The efficacy of this ''Internet?'' approach was demonstrated through an application in Tangshan, China. Field-based verification indicated that the overall mean absolute percentage error of the proposed ''Internet?'' approach in assessing the total floor area of the addressed buildings was 4.64 %. The verification also showed that the overall consistency between the estimated structural types using the proposed approach and the actual structural types of the buildings with structural type uncertainties could reach 97.54 %, with a kappa coefficient of 0.94. Because of its good accuracy, noteworthy speed, substantial labor savings, negligible cost and distinctive capability in covering large areas in near real time, this ''Internet?'' approach might have promising prospects in actual seismic loss risk reduction challenges.

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Seismic hazard assessment for Iran in terms of macroseismic intensity

Shabani,

Albarello,

Mahsuli

et al. 2024

Bull Earthquake Eng

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We present the results of probabilistic seismic hazard assessment for Iran based on a statistical procedure specifically developed to manage macroseismic intensity data. This method takes into careful consideration the specific features of such data, which are characterized as ordinal, discrete, and confined within a finite interval, ensuring a logically coherent approach throughout the analysis. The results of our assessment are then compared with hazard maps generated using a standard approach, putting in evidence significant differences both on a national scale and relative to individual cities. This comparative analysis will be useful in identifying areas of utmost concern, where further studies are strongly recommended to yield hazard estimates of greater robustness and reliability. By pinpointing these critical scenarios, we aim to guide future research endeavors towards providing more accurate and reliable seismic hazard estimates. Identifying these critical situations facilitates the prioritization of resources and interventions, ultimately enhancing seismic risk mitigation efforts across Iran.

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Exposure Estimation from Multi-Resolution Optical Satellite Imagery for Seismic Risk Assessment

Cited by 30 publications

References 20 publications

A Multiscale Exposure Model for Seismic Risk Assessment in Central Asia

A Multiscale Exposure Model for Seismic Risk Assessment in Central Asia

“Internet+” approach to mapping exposure and seismic vulnerability of buildings in a context of rapid socioeconomic growth: a case study in Tangshan, China

Seismic hazard assessment for Iran in terms of macroseismic intensity

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