Acquire competence in the execution and analysis of data from terrestrial physics and environmental experiments
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Programme
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2. Introduction to Python, matrices and vectors, functions
3. Recall to Fourier series and transform. Transfer function, causality, dispersion.
4. Python Exercise, Pulse Response
5. Sampling theorem, aliasing, analytical signal, signal energy
6. Python Exercise, Fourier Transform, FFT
7. Time series
8. Python Exercise, Least Squares problem and Data fitting
9. Introduction to Climate Change
10. Exercise on a time series (CO2 concentration in the atmosphere)
11. Earthquakes and propagation of waves
12. Exercise on a time series (CO2 concentration in the atmosphere)
13. Maxwell equations, constitutive relations
14. Exercise on a time series (CO2 concentration in the atmosphere)
15. Low frequency and high frequency electromagnetic measurements
16. Exercise on Earthquake location
17. Relation between electrical parameters and hydraulic parameters: electrical conductivity and hydraulic permeability
18. Exercise on Earthquake location
19. Hydrodynamic dispersion equation
20. Exercise on the diffusion of a pollutant
• A. R. Von Hippel, Dielectric and Waves, John Wiley & Sons.
• F. W. Taylor, Elementary Climate Physics, Oxford.
Programme
1. Introduction to the Course, Earth Physics and the Environment2. Introduction to Python, matrices and vectors, functions
3. Recall to Fourier series and transform. Transfer function, causality, dispersion.
4. Python Exercise, Pulse Response
5. Sampling theorem, aliasing, analytical signal, signal energy
6. Python Exercise, Fourier Transform, FFT
7. Time series
8. Python Exercise, Least Squares problem and Data fitting
9. Introduction to Climate Change
10. Exercise on a time series (CO2 concentration in the atmosphere)
11. Earthquakes and propagation of waves
12. Exercise on a time series (CO2 concentration in the atmosphere)
13. Maxwell equations, constitutive relations
14. Exercise on a time series (CO2 concentration in the atmosphere)
15. Low frequency and high frequency electromagnetic measurements
16. Exercise on Earthquake location
17. Relation between electrical parameters and hydraulic parameters: electrical conductivity and hydraulic permeability
18. Exercise on Earthquake location
19. Hydrodynamic dispersion equation
20. Exercise on the diffusion of a pollutant
Core Documentation
• J. Gaskill, Linear systems, Fourier transforms, and optics, Wiley.• A. R. Von Hippel, Dielectric and Waves, John Wiley & Sons.
• F. W. Taylor, Elementary Climate Physics, Oxford.
Type of delivery of the course
Frontal lectures at the blackboard and with slides projection, intercalated with numerical exercises in Python environment and laboratory experiences.Type of evaluation
The examination consists in the preparation of three reports concerning the analysis of geophysical data obtained from laboratory measurements, and from an oral test during which the reports presented by the student and the topics dealt with during the course are discussed. teacher profile teaching materials
Programme
See the course owner's profileCore Documentation
See the course owner's profileType of delivery of the course
See the course owner's profileType of evaluation
See the course owner's profile