Faults and their geometry. Strike, dip, rake and slip Brittle deformation and stresses. Tensile cracking. Shear fracture and Coulomb criterion Frictional sliding. Byerlee’s law Stresses and faulting. Stress cycle and Stick slip. -- NOTE: This course was recorded automatically in slots of one hour and processed without human intervention. Lectures are split between videos; their starting time may not coincide with the beginning of videos and intervals were not removed.

Equivalent body forces. Moment density tensor. Shear Dislocation Far. source condition. Moment tensor. Seismic moment. Double couple. Faults and moment tensor components. Application to a specific case. -- NOTE: This course was recorded automatically in slots of one hour and processed without human intervention. Lectures are split between videos; their starting time may not coincide with the beginning of videos and intervals were not removed.

Extended faults. Haskell model. Rupture time.  Directivity. Source spectra. Omega square model Seismometry. Inertial instruments. Mechanical and electromagnetic instruments Response curves. -- NOTE: This course was recorded automatically in slots of one hour and processed without human intervention. Lectures are split between videos; their starting time may not coincide with the beginning of videos and intervals were not removed.

Rheology. Viscoelasticity. Standard Linear Solid. Complex moduli. Intrinsic Attenuation. Q in the Earth. Intrinsic Dispersion. -- NOTE: This course was recorded automatically in slots of one hour and processed without human intervention. Lectures are split between videos; their starting time may not coincide with the beginning of videos and intervals were not removed.

Impulse response and Transfer function. Transformed domain. Convolution theorem. Spherically symmetric problem. Lamè theorem. GF in a isotropic and homogeneous medium. Near and far field. Response to a double-couple. Near, intermediate and far field. -- NOTE: This course was recorded automatically in slots of one hour and processed without human intervention. Lectures are split between videos; their starting time may not coincide with the beginning of videos and intervals were not removed.

Astatic instruments. Digital signals. Sampling and dynamic range. Broad band instruments. Feedback and Force balance. Strong motion. Noise. -- NOTE: This course was recorded automatically in slots of one hour and processed without human intervention. Lectures are split between videos; their starting time may not coincide with the beginning of videos and intervals were not removed.

Intensity. Magnitude. ML, mb, MS. Saturation. Similarity conditions: geometric and dynamic. Moment Magnitude. -- NOTE: This course was recorded automatically in slots of one hour and processed without human intervention. Lectures are split between videos; their starting time may not coincide with the beginning of videos and intervals were not removed.

The structure of the Earth from the surface to the core. Tomography as inverse problem. Introduction to the seismic tomography: Body-wave tomography, Surface wave tomography. -- NOTE: This course was recorded automatically in slots of one hour and processed without human intervention. Lectures are split between videos; their starting time may not coincide with the beginning of videos and intervals were not removed.

Waveform modeling and inversion. Non double couple seismic sources. Isotropic and CLVD components. Different approximation of seismic source inversion. Moment tensor inversion. -- NOTE: This course was recorded automatically in slots of one hour and processed without human intervention. Lectures are split between videos; their starting time may not coincide with the beginning of videos and intervals were not removed.

Faults and their geometry. Strike, dip, rake and slip Brittle deformation and stresses. Tensile cracking. Shear fracture and Coulomb criterion Frictional sliding. Byerlee’s law Stresses and faulting. Stress cycle and Stick slip. -- NOTE: This course was recorded automatically in slots of one hour and processed without human intervention. Lectures are split between videos; their starting time may not coincide with the beginning of videos and intervals were not removed.

Elastodynamic basic theorems. Elastodynamic Green function. Representation theorem. -- NOTE: This course was recorded automatically in slots of one hour and processed without human intervention. Lectures are split between videos; their starting time may not coincide with the beginning of videos and intervals were not removed.

Elastodynamic basic theorems. Elastodynamic Green function. Representation theorem. -- NOTE: This course was recorded automatically in slots of one hour and processed without human intervention. Lectures are split between videos; their starting time may not coincide with the beginning of videos and intervals were not removed.

Equivalent body forces. Moment density tensor. Shear Dislocation Far. source condition. Moment tensor. Seismic moment. Double couple. Faults and moment tensor components. Application to a specific case. -- NOTE: This course was recorded automatically in slots of one hour and processed without human intervention. Lectures are split between videos; their starting time may not coincide with the beginning of videos and intervals were not removed.

Impulse response and Transfer function. Transformed domain. Convolution theorem. Spherically symmetric problem. Lamè theorem. GF in a isotropic and homogeneous medium. Near and far field. Response to a double-couple. Near, intermediate and far field. -- NOTE: This course was recorded automatically in slots of one hour and processed without human intervention. Lectures are split between videos; their starting time may not coincide with the beginning of videos and intervals were not removed.

Faulting and radiation pattern. Basic fault plane solutions. Faults and plates. -- NOTE: This course was recorded automatically in slots of one hour and processed without human intervention. Lectures are split between videos; their starting time may not coincide with the beginning of videos and intervals were not removed.

Faulting and radiation pattern. Basic fault plane solutions. Faults and plates. -- NOTE: This course was recorded automatically in slots of one hour and processed without human intervention. Lectures are split between videos; their starting time may not coincide with the beginning of videos and intervals were not removed.

Extended faults. Haskell model. Rupture time.  Directivity. Source spectra. Omega square model Seismometry. Inertial instruments. Mechanical and electromagnetic instruments Response curves. -- NOTE: This course was recorded automatically in slots of one hour and processed without human intervention. Lectures are split between videos; their starting time may not coincide with the beginning of videos and intervals were not removed.

Astatic instruments. Digital signals. Sampling and dynamic range. Broad band instruments. Feedback and Force balance. Strong motion. Noise. -- NOTE: This course was recorded automatically in slots of one hour and processed without human intervention. Lectures are split between videos; their starting time may not coincide with the beginning of videos and intervals were not removed.

Intensity. Magnitude. ML, mb, MS. Saturation. Similarity conditions: geometric and dynamic. Moment Magnitude. -- NOTE: This course was recorded automatically in slots of one hour and processed without human intervention. Lectures are split between videos; their starting time may not coincide with the beginning of videos and intervals were not removed.

Rheology. Viscoelasticity. Standard Linear Solid. Complex moduli. Intrinsic Attenuation. Q in the Earth. Intrinsic Dispersion. -- NOTE: This course was recorded automatically in slots of one hour and processed without human intervention. Lectures are split between videos; their starting time may not coincide with the beginning of videos and intervals were not removed.

General formulation. Explicit linear discrete case. Equi-, Over-, Under-determined problems. Introduction to the seismological inverse problems. -- NOTE: This course was recorded automatically in slots of one hour and processed without human intervention. Lectures are split between videos; their starting time may not coincide with the beginning of videos and intervals were not removed.

General formulation. Explicit linear discrete case. Equi-, Over-, Under-determined problems. Introduction to the seismological inverse problems. -- NOTE: This course was recorded automatically in slots of one hour and processed without human intervention. Lectures are split between videos; their starting time may not coincide with the beginning of videos and intervals were not removed.

The structure of the Earth from the surface to the core. Tomography as inverse problem. Introduction to the seismic tomography: Body-wave tomography, Surface wave tomography. -- NOTE: This course was recorded automatically in slots of one hour and processed without human intervention. Lectures are split between videos; their starting time may not coincide with the beginning of videos and intervals were not removed.

Waveform modeling and inversion. Non double couple seismic sources. Isotropic and CLVD components. Different approximation of seismic source inversion. Moment tensor inversion. -- NOTE: This course was recorded automatically in slots of one hour and processed without human intervention. Lectures are split between videos; their starting time may not coincide with the beginning of videos and intervals were not removed.

Green’s function in layered media. Lithosphere and asthenosphere in the Italian region. -- NOTE: This course was recorded automatically in slots of one hour and processed without human intervention. Lectures are split between videos; their starting time may not coincide with the beginning of videos and intervals were not removed.