Unit SEISMIC AND GEOTECHNICAL RISK
- Course
- Safety engineering for the territory and the built environment
- Study-unit Code
- A002267
- Curriculum
- In all curricula
- Teacher
- Manuela Cecconi
- CFU
- 11
- Course Regulation
- Coorte 2022
- Offered
- 2022/23
- Type of study-unit
- Obbligatorio (Required)
- Type of learning activities
- Attività formativa integrata
GEOTECHNICAL SAFETY
Code | A002269 |
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CFU | 5 |
Teacher | Manuela Cecconi |
Teachers |
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Hours |
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Learning activities | Caratterizzante |
Area | Ingegneria della sicurezza e protezione civile, ambientale e del territorio |
Academic discipline | ICAR/07 |
Type of study-unit | Obbligatorio (Required) |
Language of instruction | Italian |
Contents | Introduction to Soil Mechanics and basic concepts of Rock Mechanics. Principles of Earthquake Geotechnical Engineering Design criteria and stability verifications aimed at the safety of geotechnical works/systems in both static and seismic conditions. |
Reference texts | 1. Lectures notes. 2. Geotecnica di R. Lancellotta, edito da Zanichelli. 3. Meccanica delle Rocce_Teoria e Applicazioni nell'Ingegneria_a cura di Rotonda T. et al (Hevelius Edizioni_Edizioni Efesto) 4. "Geotechnical Earthquake Engineering" di Kramer, 1996, Prentice Hall. 5. Specialised scientific papers. 6. Technical codes (NTC2018) |
Educational objectives | The purpouse of this course is to introduce the Student to the concepts, theories and procedures of Geotechnical Engineering (both rock masses and soil deposits) finalized to the safety and protection of geotechnical systems in static and seismic conditions. |
Prerequisites | In order to fully understand the topics of this Course, Students have to know the basic concepts of Geotechnics, dealt with during the basic courses of a 3-years Degree in Civil Engineering. |
Teaching methods | E-learning activities + Face to face (4 hours per week) in class. Presentation of case studies and numerical examples in class. Possible field trips. The teaching material is available on https://www.unistudium.unipg.it/ |
Other information | Attending the lessons is optional but strongly suggested. |
Learning verification modality | Oral exam. The exam will take not more than 45 min. The exam is aimed at verifying: a) the level of knowledge; b) the ability of the Student to discuss possible design solutions aimed at verifying the safety of geotechnical works and systems in seismic areas. |
Extended program | References of Soil Mechanics and basic concepts of Rock Mechanics. Dynamic soil properties from in situ investigations and laboratory testing. Seismic actions. Design criteria and stability verifications for excavation cuts, natural rock/soil slopes and other geotechnical works/systems. Pseudostatic and Newmark-type pseudodynamic approaches. Numerical examples and case hystories. |
Code | A002268 |
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CFU | 6 |
Teacher | Francesco Ponziani |
Teachers |
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Hours |
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Learning activities | Caratterizzante |
Area | Ingegneria della sicurezza e protezione civile, ambientale e del territorio |
Academic discipline | GEO/11 |
Type of study-unit | Obbligatorio (Required) |
Language of instruction | Italian |
Contents | The program includes: historical development of seismology; propagation of seismic waves, interpretation of seismograms and localizations; earthquake sources, magnitude and size; statistical laws, geodesy; seismotectonics; seismometry; seismic risk and civil protection systems; seismic microzonation; seismic prospecting. |
Reference texts | Stein, S., Wysession, M. (2003). An Introduction to Seismology, Earthquakes, and Earth Structure, Blackwell Publishing. Shearer, P. M. (2011). Introduction to Seismology, 2nd edition. Cambridge. Lay, T., Wallace, T.C. (1995). Modern Global Seismology. Academic Press. Treatise of Geophysics, 2nd edition (2015). Elsevier. Metodi didattici materiale audiovisivo e lezioni preregistrate; lezioni frontali; esercitazioni - sopralluoghi. Modalità di verifica dell'apprendimento L'esame prevede una prova orale, che consiste in un colloquio della durata di circa 45 minuti sugli argomenti trattati durante il corso e approfonditi nei testi consigliati.La prova è finalizzata ad accertare il livello di conoscenza e comprensione degli argomenti trattati nel corso, la capacità di trovare soluzioni a problemi specifici in materia di riduzione del rischio sismico e la proprietà di linguaggio ed esposizione. Programma esteso Sviluppo storico della sismologia: descrizione delle principali problematiche. Onde elastiche : equazione delle onde, onde di volume, onde di superficie, principi di Huygens e Fermat , legge di Snell ; equazioni di Zoeppritz-Knott, riduzione dell'ampiezza sismica con la propagazione, diffrazione. Interpretazione dei sismogrammi: soluzione del problema inverso. Localizzazione ipocentrale: singola stazione, multiple stazioni, localizzazioni relative. Determinazione della struttura interna della Terra. Sorgente dei terremoti : Faglie, rimbalzo elastico, ciclo sismico, meccanismi focali, tensore momento, stress drop. Dimensione dei terremoti: definizione di magnitudo, magnitudo di eventi locali, magnitudo di eventi distanti, saturazione della magnitudo, magnitudo momento, energia, intensità. Terremoti e statistica : legge di Gutenberg Richter, legge di Omori, legge di Bath. Terremoti e geodesia: misurare le deformazioni del suolo tramite GPS e SAR, deformazioni cosismiche e intersismiche. Sismotettonica: struttura e dinamica della litosfera; sismotettonica in Italia. Previsione dei terremoti e trasferimento dello stress: ciclo dei terremoti, precursori, stress statico, stress dinamico. Sismometria: principi generali, funzionamento dei sismografi, tipologie di acquisitori e sensori. Reti sismiche ed accelerometriche: specifiche e campi di applicazione. La Rete Sismica Nazionale dell’INGV e la Rete Accelerometrica Nazionale del DPCN. Esempi applicativi. Rischio sismico: Definizione del rischio sismico. Sismicità in Italia, sviluppo della classificazione sismica. Pericolosità, vulnerabilità e rischio sismico. Cenni di multirischio, piani di protezione civile. La protezione civile in Italia. Microzonazione sismica: concetti, metodologie e strumenti. Aspetti normativi. Condizione Limite di Esistenza. Prospezioni sismiche : applicazioni di interesse ingegneristico. Metodologie di superficie ed in foro in fase P ed S, tomografia sismica, monitoraggi vibrometrici: strumentazione. Tecniche di rapporti spettrali finalizzate alla microzonazione sismica. Kramer, A.L. (1996). Geotechnical Earthquake Engineering. Prentice Hall College. New Manual of Seismological Observatory Practice (NMSOP-2). http://bib.telegrafenberg.de/publizieren/vertrieb/nmsop/ Nori, L., Di Marcantonio, P. Manuale pratico di risposta sismica locale. Dal sismogramma allo spettro di progetto conRexel e Strata. EPC editore. |
Educational objectives | - theoretical bases on earthquake physics and on useful parameters to describe seismic events; - theoretical bases on seismic risk and on techniques for assessing and reducing seismic risk. The main skills will be: - ability to critically view seismic processes and their hazard; - integrated vision of seismic risk and practical applications on risk reduction; - exhibition synthesis capacity and the use of appropriate technical scientific language. |
Prerequisites | The knowledge of the basic notions of mathematics and physics is required. |
Teaching methods | Audiovisual material and pre-recorded lessons; frontal lessons; exercises - inspections |
Learning verification modality | The exam includes an oral test, which consists of an interview lasting about 45 minutes on the topics covered during the course and deepened in the recommended texts. The test is aimed at ascertaining the level of knowledge and understanding of the topics covered in the course, the ability to find solutions to specific problems regarding seismic risk reduction and the property of language and exposure. |
Extended program | Historical development of seismology: description of the main problems. Elastic waves: wave equation, body waves, surface waves, Huygens and Fermat principles, Snell's law; Zoeppritz-Knott equations, reduction of seismic amplitude with propagation, diffraction. Interpretation of seismograms: solution of the inverse problem. Hypocentral location: single station, multiple stations, relative locations. Determination of the internal structure of the Earth. Earthquake source: Faults, elastic rebound, seismic cycle, focal mechanisms, moment tensor, stress drop. Earthquake size: definition of magnitude, magnitude of local events, magnitude of distant events, saturation of magnitude, moment magnitude, energy, intensity. Earthquakes and statistics: Gutenberg Richter's law, Omori's law, Bath's law. Earthquakes and geodesy: measure soil deformations by GPS and SAR, cosismic and intersismic deformations. Seismotectonics: structure and dynamics of the lithosphere; seismotectonics in Italy. Earthquake prediction and stress transfer: earthquake cycle, precursors, static stress, dynamic stress. Seismometry: general principles, operation of seismographs, types of acquisitors and sensors. Seismic and accelerometric networks: specifications and fields of application. The National Seismic Network of the INGV and the National Accelerometric Network of the DPCN. Application examples. Seismic risk: Definition of seismic risk. Seismicity in Italy, development of seismic classification. Hazard, vulnerability and seismic risk. Elements of multirisk, civil protection plans. Civil protection in Italy. Seismic microzonation: concepts, methodologies and tools. Regulatory aspects. Limit Condition of Existence. Seismic prospecting: applications of engineering interest. Surface and borehole methodologies in P and S phase, seismic tomography, vibrometric monitoring: instrumentation. Spectral relationship techniques aimed at theseismic microzonation |