GIS TOOL FOR CALCULATING REPAIR COST OF BUILDINGS DUE TO EARTHQUAKE EFFECTS (CCRE CISMID) Miguel Estrada Carlos Zavala Fernando Lazares Jorge Morales Japan Peru Center for Earthquake Engineering Research and Disaster Mitigation Faculty of Civil Engineering National University of Engineering Lima Peru Disaster Management Cycle Disaster Cycle Pre event Event Post Event Software Hardware
Hazard Earthquakes, Landslides, Tsunamis Risk Components Exposition People, Properties Disaster Risk Vulnerability Susceptibility to natural hazards Risk = Function (Hazard, Exposition, Vulnerability) Risk Components Hazard Basically without changes but there is Climate Change Reduction Exposition Resettlement of people and properties Risk disaster reduction Vulnerability Increment of the building resistance
Seismic Hazard Peruvian Seismicity 82 80 78 76 74 72 70 Seismic Hazard Peruvian Coast Earthquakes with Magnitude > 5 1973 2010 0 0 Colombia Ecuador 2 2 4 4 6 6 Brazil 8 8 10 10 PERÚ 12 12 14 14 OCÉANO PACÍFICO Profundida Focal Bolivia 16 16 Lagos < 50 km 50km - 100 km 18 18 > 100 km Chile 0 50 100 200 300 400 Kilómetros 20 20 82 80 78 76 74 72 70
Seismic Hazard Recent earthquake with magnitude greater than 7 and that produced tsunami Focusing in Assess the Vulnerability All these reasons make the necessity to develop a practical tool to identify the vulnerable urban areas due to effects of a big earthquake. This tool is based in three aspects: Seismicity of the area Soil conditions Structural characteristics of the buildings
Soil Conditions To determine the type of soil and its response in case of an earthquake some field survey are conducted: Borehole exploration, Shear wave measurements, Microtremor measurements, A geotechnical map is developed, and Acceleration map for an earthquake scenario is developed. Soil Conditions Acceleration Map Acceleration Map for and Earthquake Scenario Soil Type Description Amp. Factor S1 Rocks 1.0 S2 Intermediate 1.2 S3 Soft soil 1.4 S4 Special case To be determined
Structural Characteristics of Buildings High social class Structural Characteristics of Buildings Middle social class
Structural Characteristics of Buildings Low social class Structural Characteristics of Buildings Cadastral information Field Value Description Use Material Conservation 0 1 2 3 4 0 1 2 3 4 0 1 2 3 4 Height Number Number of stories Empty Individual House Multifamily House Commerce Public buildings (School, Hospital, Police) Empty Adobe or quincha Masonry Reinforced concrete Others Empty Good Regular Bad Very bad
SANTA ANITA EL AGUSTINO SAN BORJA SANTA ANITA SANTIAGO DE SURCO SAN JUAN DE MIRAFLORES ATE VITARTE LA MOLINA VILLA MARIA DEL TRIUNFO PACHACAMAC CIENEGUILLA Thematic Maps 8666000 285000 286000 287000 288000 Material 289000 290000 291000 292000 293000 294000 295000 296000 8666000 Number of Stories 8659000 8659000 8662000 8662000 8663000 8663000 8664000 8661000 8664000 8665000 8665000 Material Mampostería 8661000 Concreto 8660000 Acero No Evaluado 8660000 285000 286000 287000 288000 289000 290000 291000 292000 293000 294000 295000 296000 Land Use Structural System 6 Districts in Lima Under Detailed Study 77 10'0"W 77 5'0"W 77 0'0"W 76 55'0"W 76 50'0"W La Molina Chorrillos Villa el Salvador San Juan de Lurigancho Comas Puente Piedra 11 50'0"S 11 55'0"S 12 0'0"S 12 5'0"S 12 10'0"S Santa Rosa Ü La Punta Ancón Carabayllo Puente Piedra Ventanilla Comas San Juan de Lurigancho Los Olivos Lurigancho Independencia Chaclacayo Callao Rimac San Martín de Porres Ate El Agustino Carmen de la Legua Reynoso Santa Anita Lima Bellavista Breña La Perla La Victoria San MiguelPueblo Libre Jesús María San Luis Lince Cieneguilla La Molina Magdalena del Mar San Isidro San Borja Surquillo Miraflores Santiago de Surco Barranco Distritos San Juan de Miraflores Pachacamac Villa MarÍa del TriunfoProyectoMV 11 50'0" 11 55'0" 12 0'0"S 12 5'0"S 12 10'0" Distrito Área(km2) Población aproximada en miles Chorrillos 38.9 262.6 Villa el Salvador 35.5 381.8 San Juan de Lurigancho 131.3 898.4 La Molina 65.8 132.5 Puente Piedra 71.2 233.6 Comas 48.8 487 12 15'0"S 77 10'0"W 77 5'0"W Chorrillos 0 2.5 5 10 15 20 Kilómetros 77 0'0"W Villa el Salvador 76 55'0"W MVCyS-BID 12 15'0" Lurin Punta Hermosa 76 50'0"W Aproximatelly: 2.4 millon peoples
Adopted seismic Risk Evaluation Take plaster of walls S/. Put wire mesh S/. Put new plasters/. Paint S/. Retrofitting Cost Building Earthquake damage Retroffiting Cost = Function (Structure Type, PGA, Damage level) Urban Inventory Seismic Microzoning Vulnerability Laboratoty Test Adopted seismic Risk Evaluation Building Damage Level Fundamental Period T= 0.07 Np (1+ 0.75. Z. g/981) Sa = Aceleración on Microzone w= 2 /T Sd= Sa /w 2 e= Sd H =drift i= e x (0.75 R) = FR* i ZUSC Xi Xi 1 R 0. 75 2 h 2 T
USING DAMAGE MATRIX AND PARAMETERS FROM 6 DISTRICT STUDY A RATIO DAMAGE LEVEL AND RETRIFFTING COST WAS DEVELOPED Proyecto CISMID-PGT-BID Di strito Lotes/Mza Area Lo te Prom(m2) Re posición (US$/m2) SAN JU AN DE LURI GANCHO 20 130 275 COMAS 18 160 300 PUENTE PIEDRA 18 160 235 VILLA EL SALVADOR 20 130 400 CHORRILLOS 18 160 950 LA MOLINA 18 250 1300 RATIO DAMAGE AND RETROFIT COST BASE ON SOCIOECONOMICAL LEVEL (Source: APEIN)
Structural Characteristics of Buildings Development of Building Damage Curve Damage curve based on the drift of the building The damage curve will depend on the parameters mentioned in the table showed before. Structural Damage of Water Pipes Number of breaks per kilometer for different type of water pipe
Data Integration in a GIS Platform Soil Conditions Building Information Water pipe information Analysis Tool Development
Analysis Tool Development Development within the commercial software ArcGIS v10.0 By programming in Python language Using Arcpy and Math modules The program offers flexibility to change building and soil parameters Analysis Tool Application Tacna City Southern Peru Buildings Soils Water pipes
Analysis Tool Application Tacna City Southern Peru Conclusions An automatic tool to evaluate the building and water pipe damage has been developed. To carry out the damage assessment procedure geotechnical, cadastral and pipe information is necessary. However, the building information could be in different area sizes: Lot, Block or Zone, depending the quantity or quality of the data. The tools can be applied to cities with similar building, pipe and soil conditions similar to Lima city. To obtain empirical relationships between acceleration and level of damage, it has processed a wide variety of cases, so the application is well calibrated for this type of buildings and soils. Regarding the analysis for water pipe some additional curves may be develop, to cover the variety of pipe materials and diameters, but this tools can give a good figure about the possible damage in case an severe earthquake. Statistical information can be obtained from the final thematic maps and can be used to make prevention and mitigation plans.
Group 4 Group 4 and 5 Conclusions Inventory map for Lima City and Tacna City based on Satellite Imagery and Census Data will continue to developing To improve the inventory data Peruvian Counterpart will contact to Municipalities to get cadastral data. For building high LIDAR may be used, for this purpose Peruvian counterpart will request the quotation to a private company. Sharing PRISM satellite data with INDECI and CONIDA will be carried out to analyse DSM. Future activities: Complete the building inventory for Lima and Tacna Join effort with Group 1 and 3 to develop damage assessment maps Developing damage detection techniques Installation of permanent GPS monitoring system at CISMID Setup of several GPS monitoring point and conduct the correspond measurement Group 5 New Peruvian Government planning issues for Pisco Recovery was discussed. Japanese Urban Planners will study the future land use of Pisco and will provide some recommendations Master plan map of Pisco will be share and feedback will discussed by Peruvian and Japanese specialists. Propose a way to increase the peoples sensitivity related to Disaster Management Issues. Group 4 and 5 Conclusions Master Plan for Pisco 2011 2021