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Martingales with Applications to Finance


Unit code: MATH37001
Credit Rating: 10
Unit level: Level 3
Teaching period(s): Semester 1
Offered by School of Mathematics
Available as a free choice unit?: N

Requisites

Prerequisite

Additional Requirements

Please note

Students are not permitted to take more than one of MATH37001 or MATH47201 for credit in the same or different undergraduate year.

 

Students are not permitted to take MATH47201 and MATH67201 for credit in an undergraduate programme and then a postgraduate programme.

 

Note that MATH67201 is an example of an enhanced level 3 module as it includes all the material from MATH37001

 

When a student has taken level 3 modules which are enhanced to produce level 6 modules on an MSc programme taken within the School of Mathematics, then they are limited to a maximum of two such modules (with no alternative arrangements available otherwise)

 

 

Aims

To provide a firm grasp of a range of basic concepts and fundamental results in the theory of martingales and to give some simple applications in the rapid developing area of financial mathematics.

Overview

An introduction to a circle of ideas and fundamental results of the theory of martingales, which play a vital role in stochastic calculus and in the modern theory of finance.

Learning outcomes

On successful completion of this course unit students will be able to:

  • compute integrals of simple random variables with respect to a probability measure and apply the dominated, monotone convergence theorems;
  • use the computational rules of conditional expectation and prove that a given stochastic process is a martingale;
  • apply Doob Optional Sampling Theorem to calculate interesting probabilities concerning some practical problems, e.g. the gambler ruin problem;
  • answer simple questions about self-financing portfolios and complete markets;
  • determine when a financial market is arbitrage-free;
  • find out a replicating strategy for a financial claim;
  • calculate the fair price of a financial claim in a financial market.

Assessment Further Information

End of semester examination: two hours weighting 100%

Syllabus

  • Probability spaces, events, Ï'-fields, probability measures and random variables. Integration with respect to a probability measure. Convergence theorems (dominated, monotone and Fatou). [5]
  • Conditional expectations. Fair games and martingales, submartingales and supermartingales. Doob decomposition theorem. Stopping times and the optional sampling theorem. The upcrossing inequality and the martingale convergence theorem. The Doob maximal inequality and the martingale modification theorem. [13]
  • Applications. Discrete time random models in financial markets. Price processes, self-financing portfolio and value processes. Arbitrage opportunities and equivalent martingale measures. Completeness of the markets. Options and option pricing. [6]

Recommended reading

  • O. Kallenberg, Foundations of Modern Probability, Springer-Verlag, 2001.
  • N. H. Bingham and R. Kiesel, Risk-Neutral Valuation, Springer-Verlag, 1998.
  • D. Williams, Probability with Martingales, Cambridge Univ. Press, 1991.
  • A. N. Shiryaev, Probability, Springer-Verlag, 1996.

Feedback methods

Feedback tutorials will provide an opportunity for students' work to be discussed and provide feedback on their understanding.  Coursework or in-class tests (where applicable) also provide an opportunity for students to receive feedback.  Students can also get feedback on their understanding directly from the lecturer, for example during the lecturer's office hour.
 

Study hours

  • Lectures - 22 hours
  • Tutorials - 11 hours
  • Independent study hours - 67 hours

Teaching staff

Tusheng Zhang - Unit coordinator

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