TMA285 / MMA712 Financial derivatives and partial differential equations
The main topic of the course "Financial derivatves and PDE's" is the theoretical valuation of financial derivatives based on the arbitrage-free principle and using methods from stochastic calculus and partial differential equations.
This page contains the program of the course: lectures, exercise sessions and computer labs. Other information, such as learning outcomes, teachers, literature and examination, are in a separate course PM.
Teacher and student representatives
Teacher and examiner: Moritz Schauer (smoritz@chalmers.se)
Student representatives
Literature
Basic financial concepts (PDF ). Read this by yourself during the first week.
Stochastic Calculus, Financial Derivatives and PDE's. (PDF)
Errata: pdf
Additional recommended (optional) reading:
Steven E. Shreve. Stochastic Calculus for Finance II. Continuous-Time Models (Springer).
Program
The schedule of the course is in TimeEdit.
The week plan is preliminary and might be changed during the course.
Lectures
| Week | Day | Time and place | Sections | Slides |
|---|---|---|---|---|
| 3 |
16/01 | 8:00 - 9:45 Euler | Introduction. Probability spaces, random variables, distribution functions (Ch 1, 2) | TMA285_MMA711_230117.pdf |
| 17/01 | 10:00-11:45 Pascal | Lebesgue integral, expectation. Change of measure. | TMA285_MMA711_230118.pdf | |
| 18/01 | 13:15-15:00 Euler | Conditional expectation. Stochastic processes. Brownian motion, quadratic variation (Ch 2, 3) | TMA285_MMA711_230119.pdf | |
| 19/01 | 10:00-11:45 Vasa B, Vasa 2-3 |
Brownian motion. Martingales. Markov processes (Ch 3) |
TMA285_MMA711_230120.pdf | |
| 4 |
23/01 | 8:00 - 9:45 Euler |
Itô's integral (Ch 4) |
TMA285_MMA711_230124.pdf |
| 24/01 | 10:00-11:45 Pascal |
Itô's formula. Diffusion processes(Sec 4.6) |
||
| 25/01 | 13:15-15:00 Euler |
Diffusion processes. Girsanov's Theorem (Sec 4.5) |
||
| 26/01 | 10:00-11:45 Vasa B, Vasa 2-3 |
Exercises 2.8, 2.15, 3.3, 3.27, 4.4, 4.5, 4.6 |
|
|
| 5 | 30/01 | 8:00 - 9:45 Euler |
Stochastic differential equations Kolmogorov PDE (Sec 5.2) |
|
| 31/01 | 10:00-11:45 Pascal |
Kolmogorov PDE, Markov property, and transition density (Sec 5.2) Exercise 3.33, 5.7 |
TMA285_MMA711_230201.pdf | |
| 1/02 | 13:15-15:00 Euler |
Arbitrage-free markets (Sec 6.1) Risk-neutral formula in discrete case |
|
|
| 2/02 | 10:00-11:45 Vasa B, Vasa 2-3 |
cancelled |
|
|
| 6 | 6/02 | 8:00-9:45 Euler |
Risk-neutral pricing formula for European derivatives (Sec 6.2) |
|
| 7/02 | 10-11.45 Pascal |
Black-Scholes price of standard European derivatives (Sec 6.3) |
|
|
| 8/02 | 13:15-15:00 Euler |
Black-Scholes price of standard European derivatives (Sec 6.3) |
No notes because I followed Sec 6.3 | |
| 9/02 | 10:00-11:45 Vasa B, Vasa 2-3 |
The Asian option. (Sec 6.4). Finite difference solutions of PDE's (Sec 5.4) |
||
| 7 | 13/02 | 8:00-9:45 Euler |
Finite difference for heat equation. Crude Monte Carlo method. Control variate Monte Carlo method (Sec 6.4) |
Compendium page 134-137 |
| 14/02 | 10:00-11:45 Pascal |
Local volatility models. CEV model (Sec 6.6) |
||
| 15/02 | 13.15-15 Euler |
Local volatility models (Sec 6.6) |
|
|
| 16/02 | 10:00-11:45 Vasa B, Vasa 2-3 |
Stochastic volatility models. |
|
|
| 8 | 20/02 | 8:00-9:45 Euler |
Work on projects |
|
| 21/02 | 10:00-11:45 Pascal |
Work on projects |
|
|
| 22/02 |
13:15-15:00 Euler |
Work on projects |
|
|
| 23/02 | 10:00-11:45 Vasa B, Vasa 2-3 |
Variance swaps (Sec 6.6) |
See compendium, Sec 6.6 |
|
| 9 | 27/02 | 8:00-9:45 Euler |
Yield curve. Classical approach to ZCB pricing. |
|
| 28/02 | 10:00-11:45 Pascal | Classical approach to ZCB pricing. HJM model (Sec 6.7). | ||
| 29/02 |
13:15-15:00 Euler |
Interest rate swaps (Sec 6.7) (Sec 6.8) | ||
| 1/03 | 10:00-11:45 Vasa B, Vasa 2-3 | Forwards (Sec 6.8) | TMA285_MMA711_forwards.pdf | |
| 10 | 5/03 | 10:00-11:45 Pascal |
Futures (Sec 6.8). |
|
| 6/03 |
13:15-15:00 Euler |
Repetition/questions |
|
Examination
This course will be examined through a series of assignments and a written exam.
The minimum number of points to pass the course is 15p, of which 12p come from the written exam and 3p from the assignments.
- at GU a result greater than or equal to 24 points is graded VG;
- at Chalmers a result greater than or equal to 23 points and smaller than 25 points is graded 4 and a result greater than or equal to 25 points is graded 5.
Note that the written exam gives at most 20 points, and so is not sufficient to get VG or 5.
Assignments:
1) There are 10 exercises in Chapters 1 through 5 of the lecture notes which are marked with the symbol (☆). Awarded points: Max. 5 points. Deadline for submission: February 12th, h. 23.59. You can submit a picture of handwritten solutions, but be sure that they are clearly readable. This assignment has to be worked out individually and submitted via canvas. This assignment is not compulsory.
2) The two projects in appendix A of the lecture notes on the Asian option and the CEV model. You can use either Python (preferable) or Matlab for the computer part. Awarded points: Max. 5 points for each project. Deadline for submission: March 6th, h. 23.59. This assignment can be worked out on groups of up to 3 students. If you are looking for teammates to create a group post a message in the discussion thread. The assignments should be submitted via canvas. This assignment is not compulsory.
Together with the projects, you have to submit a statement, signed by all members of the group, certifying that this report is your own work and that all members of the group have equally contributed to the assignment. All reports will be subjected to a plagiarism check. Information on how to avoid plagiarism and on Chalmers policy on plagiarism can be found here
3) Written exam in MARCH. Awarded points: Max. 20 points. The written exam is compulsory and no aids are allowed. The exam will include practical exercises as well as theoretical questions. The list of definitions and theorems:
Definitions: 2.17, 4.4, 4.5, 6.1, 6.2, 6.3, 6.5, 6.6, 6.9, 6.11
Theorems: 6.1, 6.2, 6.3, 6.5, 6.6, 6.9, 6.11, 6.13, 6.15, 6.17, 6.18, 6.19, 6.20, 6.25, 6.27, 6.28
Some old exams can be found here: Old_Exams.zip
Course summary:
| Date | Details | Due |
|---|---|---|