Constructing Damage Indices Based on Publicly Available Spatial Data: Exemplified by Earthquakes and Volcanic Eruptions in Indonesia

Emmanuel Skoufias; Eric Strobl; Thomas Tveit

doi:10.1007/s13753-021-00348-4

International Journal of Disaster Risk Science ›› 2021, Vol. 12 ›› Issue (3) : 410 -427. DOI: 10.1007/s13753-021-00348-4

Article

Constructing Damage Indices Based on Publicly Available Spatial Data: Exemplified by Earthquakes and Volcanic Eruptions in Indonesia

Author information +

History +

PDF

Abstract

This article demonstrates the construction of earthquake and volcano damage indices using publicly available remote sensing sources and data on the physical characteristics of events. For earthquakes we use peak ground motion maps in conjunction with building type fragility curves to construct a local damage indicator. For volcanoes we employ volcanic ash data as a proxy for local damages. Both indices are then spatially aggregated by taking local economic exposure into account by assessing nightlight intensity derived from satellite images. We demonstrate the use of these indices with a case study of Indonesia, a country frequently exposed to earthquakes and volcanic eruptions. The results show that the indices capture the areas with the highest damage, and we provide overviews of the modeled aggregated damage for all provinces and districts in Indonesia for the time period 2004 to 2014. The indices were constructed using a combination of software programs—ArcGIS/Python, Matlab, and Stata. We also outline what potential freeware alternatives exist. Finally, for each index we highlight the assumptions and limitations that a potential practitioner needs to be aware of.

Keywords

Damage indices / Indonesia / Natural hazard modeling / Remote sensing data

Cite this article

Download citation ▾

Emmanuel Skoufias, Eric Strobl, Thomas Tveit. Constructing Damage Indices Based on Publicly Available Spatial Data: Exemplified by Earthquakes and Volcanic Eruptions in Indonesia. International Journal of Disaster Risk Science, 2021, 12(3): 410-427 DOI:10.1007/s13753-021-00348-4

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Anniballe R, Noto F, Scalia T, Bignami C, Stramondo S, Chini M, Pierdicca N. Earthquake damage mapping: An overall assessment of ground surveys and VHR image change detection after L'Aquila 2009 earthquake. Remote Sensing of Environment, 2018, 210: 166-178

[2]	Arias, L., J. Cifuentes, M. Marín, F. Castillo, and H. Garcés. 2019. Hyperspectral imaging retrieval using MODIS satellite sensors applied to volcanic ash clouds monitoring. Remote Sensing 11(11). https://doi.org/10.3390/rs11111393.

[3]	Atkinson, G.M., and S.I. Kaka. 2006. Relationships between felt intensity and instrumental ground motion for New Madrid ShakeMaps. Department of Earth Sciences, Carleton University, Ottawa, Canada.

[4]	Atkinson GM, Kaka SI. Relationships between felt intensity and instrumental ground motion in the Central United States and California. Bulletin of the Seismological Society of America, 2007, 97(2): 497-510

[5]

Balk DL, Deichmann U, Yetman G, Pozzi F, Hay SI, Nelson A. Hay SI, Graham AJ, Rogers DJ. Determining global population distribution: Methods, applications and data. Global mapping of infectious diseases: Methods, examples and emerging applications (Advances in Parasitology, Volume 62), 2006, Cambridge, MA: Elsevier Academic Press 119-156

[6]	Bluhm, R., and M. Krause. 2020. Top lights: Bright cities and their contribution to economic development. SoDa Laboratories Working Paper Series, Monash University, SoDa Laboratories. https://EconPapers.repec.org/RePEc:ajr:sodwps:2020-08. Accessed 10 Apr 2021.

[7]	Cao C, Shao X, Uprety S. Detecting light outages after severe storms using the S-NPP/VIIRS Day/Night Band Radiances. IEEE Geoscience and Remote Sensing Letters, 2013, 10(6): 1582-1586

[8]	Carn SA, Krueger AJ, Krotkov NA, Yang K, Evans K. Tracking volcanic sulfur dioxide clouds for aviation hazard mitigation. Natural Hazards, 2009, 51(2): 325-343

[9]	Chen X, Nordhaus W. A test of the new VIIRS lights data set: Population and economic output in Africa. Remote Sensing, 2015, 7(4): 4937-4947

[10]

CIESIN (Center for International Earth Science Information Network), IFPRI (International Food Policy Research Institute), The World Bank, and CIAT (Centro Internacional Agricultura Tropical). 2011. Global rural-urban mapping project, version 1 (GRUMPv1): Urban extents grid. Palisades, NY: NASA Socioeconomic Data and Applications Center (SEDAC).

[11]	Cooner, A.J., Y. Shao, and J.B. Campbell. 2016. Detection of urban damage using remote sensing and machine learning algorithms: Revisiting the 2010 Haiti Earthquake. Remote Sensing 8(10): Article 868.

[12]

De Groeve, T., A. Annunziato, S. Gadenz, L. Vernaccini, A. Erberik, and T. Yilmaz. 2008. Real-time impact estimation of large earthquakes using USGS Shakemaps. In Proceedings of the International Disaster and Risk Conference 2008, 25–29 August 2008, Davos, Switzerland. https://grforum.org/fileadmin/user_upload/idrc/former_conferences/idrc2008/presentations2008/De_Groeve_Tom_Real_Time_Impact_estimation_of_Large_Earthquakes_Using_UGUS_Shakemaps.pdf. Accessed 21 Jun 2015.

[13]	Dell'Acqua F, Gamba P. Remote sensing and earthquake damage assessment: Experiences, limits, and perspectives. Proceedings of the IEEE, 2012, 100(10): 2876-2890

[14]	Dong L, Shan J. A comprehensive review of earthquake-induced building damage detection with remote sensing techniques. ISPRS Journal of Photogrammetry and Remote Sensing, 2013, 84: 85-99

[15]	Douglas J. Physical vulnerability modelling in natural hazard risk assessment. Natural Hazards and Earth System Sciences, 2007, 7(2): 283-288

[16]	Elvidge C, Baugh K, Hobson V, Kihn E, Kroehl H, Davis E, Cocero D. Satellite inventory of human settlements using nocturnal radiation emissions: A contribution for the global toolchest. Global Change Biology, 1997, 3(5): 387-395

[17]	Felpeto A, Marti J, Ortiz R. Automatic GIS-based system for volcanic hazard assessment. Journal of Volcanology and Geothermal Research, 2007, 166(2): 106-116

[18]	FEMA (Federal Emergency Management Agency). 2006. HAZUS-MH MR2 technical manual. Washington, DC: FEMA.

[19]	Ferguson DJ, Barnie TD, Pyle DM, Oppenheimer C, Yirgu G, Lewi E, Kidane T, Carn S, Hamling I. Recent rift-related volcanism in Afar, Ethiopia. Earth and Planetary Science Letters, 2010, 292(3–4): 409-418

[20]	Fu B, Awata Y, Du J, Ninomiya Y, He W. Complex geometry and segmentation of the surface rupture associated with the 14 November 2001 great Kunlun earthquake, northern Tibet. China. Tectonophysics, 2005, 407(1–2): 43-63

[21]	Geiß C, Taubenböck H. Remote sensing contributing to assess earthquake risk: From a literature review towards a roadmap. Natural Hazards, 2013, 68(1): 7-48

[22]	Geiß C, Pelizari PA, Marconcini M, Sengara W, Edwards M, Lakes T, Taubenböck H. Estimation of seismic building structural types using multi-sensor remote sensing and machine learning techniques. ISPRS Journal of Photogrammetry and Remote Sensing, 2015, 104: 175-188

[23]	GFDRR (Global Facility for Disaster Reduction and Recovery). 2011. Indonesia: Advancing a national disaster risk financing strategy – Options for consideration. Report. Washington, DC: World Bank.

[24]	GHI and UNCRD (GeoHazards International and United Nations Center for Regional Development). 2001. Final report: Global Earthquake Safety Initiative (GESI) pilot project. Report. Menlo Park, CA: GHI.

[25]	Gillespie TW, Chu J, Frankenberg E, Thomas D. Assessment and prediction of natural hazards from satellite imagery. Progress in Physical Geography: Earth and Environment, 2007, 31(5): 459-470

[26]	Henderson JV, Storeygard A, Weil DN. Measuring economic growth from outer space. American Economic Review, 2012, 102(2): 994-1028

[27]	Hodler R, Raschky PA. Regional favoritism. The Quarterly Journal of Economics, 2014, 129(2): 995-1033

[28]	Hu, Y., and J. Yao. 2019. Illuminating economic growth. IMF Working Papers 2019/077, International Monetary Fund. https://www.imf.org/en/Publications/WP/Issues/2019/04/09/Illuminating-Economic-Growth-46670. Accessed 13 Apr 2021.

[29]	Jaiswal, K.S., and D.J. Wald. 2008. Creating a global building inventory for earthquake loss assessment and risk management. U.S. Geological Survey open-file report 2008–1160. Reston, VA: USGS.

[30]	Joyce KE, Belliss SE, Samsonov SV, McNeill SJ, Glassey PJ. A review of the status of satellite remote sensing and image processing techniques for mapping natural hazards and disasters. Progress in Physical Geography: Earth and Environment, 2009, 33(2): 183-207

[31]	Klinger, Y. 2005. High-resolution satellite imagery mapping of the surface rupture and slip distribution of the Mw 7.8, 14 November 2001 Kokoxili Earthquake, Kunlun Fault, Northern Tibet, China. Bulletin of the Seismological Society of America 95(5): 1970–1987.

[32]	Krotkov, N.A., and C. Li. 2006. OMI/Aura Sulphur Dioxide (SO2) Total Column 1-orbit L2 Swath 13x24 km V003 (OMSO2) at GES. Greenbelt, MD: Goddard Earth Sciences Data and Information Services Center (GES DISC).

[33]	Li X, Xu H, Chen X, Li C. Potential of NPP-VIIRS nighttime light imagery for modeling the regional economy of China. Remote Sensing, 2013, 5(6): 3057-3081

[34]	Lin C-YC. Instability, investment, disasters, and demography: Natural disasters and fertility in Italy (1820–1962) and Japan (1671–1965). Population and Environment, 2010, 31(4): 255-281

[35]	Linkimer L. Relationship between peak ground acceleration and Modified Mercalli Intensity in Costa Rica. Revista Geológica de América Central, 2007, 38: 81-94.

[36]	Michalopoulos S, Papaioannou E. National institutions and subnational development in Africa. The Quarterly Journal of Economics, 2014, 129(1): 151-213

[37]	Murphy JR, O'Brien LJ. The correlation of peak ground acceleration amplitude with seismic intensity and other physical parameters. Bulletin of the Seismological Society of America, 1977, 67(3): 877-915.

[38]	National Disaster Management Agency. 2016. DiBi database (Data and Information on Disaster in Indonesia). http://dibi.bnpb.go.id/. Accessed 10 Apr 2018.

[39]	OMI Team (Ozone Monitoring Instrument). 2012. Ozone Monitoring Instrument (OMI) data user’s guide. User manual. Washington, DC: NASA.

[40]	Platt S, Brown D, Hughes M. Measuring resilience and recovery. International Journal of Disaster Risk Reduction, 2016, 19: 447-460

[41]	Raschky, P.A. 2013. Discussion paper: Estimating the effects of West Sumatra Public Asset Insurance Program on short-term recovery after the September 2009 Earthquake. Jakarta Pusat, Indonesia: ERIA (Economic Research Institute for ASEAN and East Asia).

[42]	Shen Z, Zhu X, Cao X, Chen J. Measurement of blooming effect of DMSP-OLS nighttime light data based on NPP-VIIRS data. Annals of GIS, 2019, 25(2): 153-165

[43]	Shi K, Yu B, Huang Y, Hu Y, Yin B, Chen Z, Chen L, Wu J. Evaluating the ability of NPP-VIIRS nighttime light data to estimate the Gross Domestic Product and the electric power consumption of China at multiple scales: A comparison with DMSP-OLS data. Remote Sensing, 2014, 6(2): 1705-1724

[44]	Skoufias, E., E. Strobl, and T. Tveit. 2017. Natural disaster damage indices based on remotely sensed data: An application to Indonesia. Policy research working paper 8188. Washington, DC: World Bank.

[45]	Skoufias, E., E. Strobl, and T. Tveit. 2018. The reallocation of district-level spending and natural disasters: Evidence from Indonesia. Policy research working paper series no. WPS 8359. https://ideas.repec.org/p/wbk/wbrwps/8359.html. Accessed 5 Dec 2019.

[46]	Skoufias E, Strobl E, Tveit T. Can we rely on VIIRS nightlights to estimate the short-term impacts of natural hazards? Evidence from five South East Asian countries. Geomatics, Natural Hazards and Risk, 2021, 12(1): 381-404

[47]	Sun D, Li S, Zheng W, Croitoru A, Stefanidis A, Goldberg M. Mapping floods due to Hurricane Sandy using NPP VIIRS and ATMS data and geotagged Flickr imagery. International Journal of Digital Earth, 2015, 9(5): 427-441

[48]	Tamkuan, N., and M. Nagai. 2017. Fusion of multi-temporal interferometric coherence and optical image data for the 2016 Kumamoto Earthquake damage assessment. ISPRS International Journal of Geo-Information 6(7): Article 188.

[49]	Tan, C.E., H.J. Li, X.G. Zhang, H. Zhang, P.Y. Han, Q. An, W.J. Ding, and M.Q. Wang. 2009. The impact of the Wenchuan Earthquake on birth outcomes. PLOS ONE 4(12): Article e8200.

[50]	Taubenböck H, Geiß C, Wieland M, Pittore M, Saito K, So E, Eineder M. Shroder JF, Wyss M. The capabilities of earth observation to contribute along the risk cycle. Earthquake hazard, risk, and disasters, 2014, Cambridge, MA: Elsevier Academic Press 25-53

[51]	Tralli DM, Blom RG, Zlotnicki V, Donnellan A, Evans DL. Satellite remote sensing of earthquake, volcano, flood, landslide and coastal inundation hazards. ISPRS Journal of Photogrammetry and Remote Sensing, 2005, 59(4): 185-198

[52]	Tveit, T. 2017. Essays on the economics of natural disasters. Ph.D. dissertation. University of Cergy-Pontoise, France. http://www.theses.fr/2017CERG0950. Accessed 5 Dec 2019.

[53]	USGS (United States Geological Survey). 2019. USGS landsat collection. https://www.usgs.gov/land-resources/nli/landsat. Accessed 6 Dec 2019.

[54]	Wald DJ, Quitoriano V, Heaton TH, Kanamori H, Scrivner CW, Worden CB. TriNet “ShakeMaps”: Rapid generation of peak ground motion and intensity maps for earthquakes in Southern California. Earthquake Spectra, 1999, 15(3): 537-555

[55]	Wald, D.J., B.C. Worden, V. Quitoriano, and K.L. Pankow. 2005. ShakeMap manual – Technical manual, user's guide, and software guide. Technical manual. Reston, VA: USGS.

[56]	Wilson G, Wilson TM, Deligne NI, Cole JW. Volcanic hazard impacts to critical infrastructure: A review. Journal of Volcanology and Geothermal Research, 2014, 286: 148-182

[57]	Worden CB, Wald DJ, Allen TI, Lin K, Garcia D, Cua G. A revised ground-motion and intensity interpolation scheme for ShakeMap. Bulletin of the Seismological Society of America, 2010, 100(6): 3083-3096

[58]

World Bank Group. 2009. West Sumatra and Jambi natural disasters: Damage, loss and preliminary needs assessment (English). Washington, DC: World Bank Group. http://documents.worldbank.org/curated/en/177951468285048532/West-Sumatra-and-Jambi-natural-disasters-damage-loss-and-preliminary-needs-assessment. Accessed 6 Dec 2019.

[59]	Wu H, Adler RF, Tian Y, Huffman GJ, Li H, Wang J. Real-time global flood estimation using satellite-based precipitation and a coupled land surface and routing model. Water Resources Research, 2014, 50(3): 2693-2717

[60]	Wyss M. Shroder JF, Wyss M. Ten years of real-time earthquake loss alerts. Earthquake hazard, risk, and disasters, 2014, Cambridge, MA: Elsevier Academic Press 143-165

[61]	Yamazaki F, Matsuoka M. Remote sensing technologies in post disaster damage assessment. Journal of Earthquake and Tsunami, 2007, 1(3): 193-210

[62]	Zhao, M., Y. Zhou, X. Li, W. Cao, C. He, B. Yu, X. Li, C.D. Elvidge, et al. 2019. Applications of satellite remote sensing of nighttime light observations: Advances, challenges, and perspectives. Remote Sensing 11(17): Article 11.