Course - Mathematical Geophysics - PG8106
PG8106 - Mathematical Geophysics
About
Examination arrangement
Examination arrangement: Oral examination
Grade: Passed / Not Passed
| Evaluation | Weighting | Duration | Grade deviation | Examination aids |
|---|---|---|---|---|
| Oral examination | 100/100 |
Course content
The course introduces the student to mathematical aspects of wave theory as used in geophysics. Focus is on seismic forward models and inversion. Theory for seismic modelling of wave propagation in horizontally layered media is developed in detail. It is shown that several seismic data processing methods like deterministic multiple removal and de-ghosting can be deduced from the modelling theory. Green's functions for the wave and Helmholz equation are given. The reciprocity theorems for acoustic and elastic media are developed. Several seismic data processing schemes which follow by using the principle of reciprocity are outlined. First, it is shown how seismic data can be injected as multiple point sources in finite-difference modelling to separate data into their upgoing and downgoing constituents, or estimate the wavefield emitted by the seismic source. Second, multidimensional deconvolution is derived to eliminate the water-layer effect from seismic data. Finally, waveform inversion of seismograms is treated for the one-dimensional wave equation.
Learning outcome
Ingress: The students should learn basic mathematical models of seismic wave theory with the focus on the solution of some specific fundamental problems.
Knowledge: The students should understand how seismic modeling and inversion is applied in petroleum exploration and production.
Skills: The students should be able to develop and apply mathematical models for seismic data processing. They should know various techniques for seismic modeling, processing and inversion.
General competence: The students learn important mathematical aspects of geophysical wave theories. They understand the main principles that are applied in petroleum seismic research. They are able to apply the learning to develop on their own models for seismic data processing and analysis. Critical self-learning is emphasized.
Learning methods and activities
Lectures and exercises.
Further on evaluation
To pass the course a score of at least 70 percent is required.
Specific conditions
Admission to a programme of study is required:
Engineering (PHIV)
Recommended previous knowledge
MSc degree in Applied Geophysics, Physics or Mathematics.
Required previous knowledge
Requires admission to the PhD programme Engineering, specialization within Geophysics, admission to the PhD programme at another Norwegian University, or approval from the person with course responsibility.
Course materials
Selected chapters from "Introduction to Petroleum Seismology" by Luc T Ikelle and Lasse Amundsen, published by Society of Exploration Geophysicists 2018 (ISBN (Print) 978-1-56080-343-0, ISBN (Online) 978-1-56080-344-7) and "Introduction to Exploration Geophysics with Recent Advances" by Martin Landrø and Lasse Amundsen, published by Bivrost 2018 (ISBN 978-82-303-3763-9). Lecture notes.
No
Version: 1
Credits:
7.5 SP
Study level: Doctoral degree level
Term no.: 1
Teaching semester: AUTUMN 2024
Language of instruction: English
Location: Trondheim
- Applied Geophysics
- Technological subjects
Department with academic responsibility
Department of Geoscience
Examination
Examination arrangement: Oral examination
- Term Status code Evaluation Weighting Examination aids Date Time Examination system Room *
- Autumn ORD Oral examination 100/100
-
Room Building Number of candidates - Spring ORD Oral examination 100/100
-
Room Building Number of candidates
- * The location (room) for a written examination is published 3 days before examination date. If more than one room is listed, you will find your room at Studentweb.
For more information regarding registration for examination and examination procedures, see "Innsida - Exams"