M.Sc. Program in Financial Mathematics in Life and Pension Insurance
Program tanımlarıThe last decades witnessed the projection of sophisticated mathematical techniques to the center of the finance industry. In the 80's the main investment banks hired mathematicians, physicists and engineers to become financial engineers. Gradually, the main skills defining this professional category are being clarified and today many universities all over the world are designing programs to develop modeling and mathematical expertise in financial applications.
In our country, the financial sector has enjoyed unparalleled expansion in the last decades and more and more sophisticated financial instruments are expected to be introduced into the sector in the forthcoming ones. Already there are serious attempts to integrate derivative securities and markets into the Turkish financial system. These developments will lead to a demand for talented people trained in the field of financial mathematics.
The Institute of Applied Mathematics is responding to this new trend in the Turkish finance industry by developing an interdisciplinary program that will introduce students to models and mathematical techniques used in option pricing, pricing of other complex financial products, and to some aspects of financial econometrics. The program combines the strengths of the departments of Mathematics, Business Administration, Economics, Statistics and Industrial Engineering of the Middle East Technical University.
The option of “Financial Mathematics in Life and Pension Insurance” focuses on life contingencies.
Objectives of the Program
The objectives of this program are
To provide students with the knowledge and skills necessary for comprehending and applying existing techniques of Financial Mathematics and Life Insurance.
To cultivate their ability in creating new, innovative techniques.
To analyze and manage financial markets.
To conduct research in risk modeling and management, interest rate models, pricing and hedging portfolio optimization.
Admission of Requirements
The admission procedure of these programs will be implemented according to the “Academic Rules and Regulations Concerning Graduate Studies of METU”. However, some programs might have additional admission requirements. University graduates of any discipline willing to acquire expertise in financial mathematics are natural candidates for these programs. These programs are also open to graduates working in financial and insurance industries. In general, the applicants will be evaluated based on their success in their graduation fields, their LES (Graduate Education Examination) scores, English Proficiency, and the result of a possible examination/interview given by the Institute.
The program is equally suitable for students who have just finished their undergraduate education or for practitioners in financial industry holding a Bachelor degree. Applicants must have a strong academic background showing good analytical skills. The applicants are expected to have working knowledge of calculus (including partial differentiation, Taylor series, Riemann-Stieltjes integrals), linear algebra (systems of equations, determinants, diagonalization of symmetric matrices, eigenvalues, etc.), elementary theory of ordinary and partial differential equations, in addition to some basic knowledge of computer programming. Course work or job experience in probability is also recommended. A promising student lacking prerequisites may be admitted but required to take the summer Mathematics Preparatory Course (MPC) before beginning the program.
M.Sc. Program-Non-Thesis Option:Financial Mathematics in Life and Pension Insurance
10 core courses
1 seminar course(non-credit)
Term Project(non-credit)
Total : 30 credits
Core Courses for Financial Mathematics in Life and Pension Insurance
IAM 520 Financial Derivatives (3-0)3
IAM 521 Financial Management (3-0)3
IAM 524 Financial Economics (3-0)3
IAM 526 Time Series Applied to Finance (3-0)3
IAM 530 Elements of Probability and Statistics (3-0)3
IAM 541 Probability Theory (3-0)3
IAM 582 Life Insurance Mathematics (3-0)3
IAM 583 Pension Fund Modeling (3-0)3
IAM 584 Advanced Actuarial Mathematics (3-0)3
IAM 746 Actuarial Risk Theory (3-0)3
IAM 590 Graduate Seminar (0-2)NC
IAM 589 Term Project (Non-credit)
Description of Core Courses for Financial Mathematics in Life and Pension Insurance
1. IAM 520 Financial Derivatives (3-0)3
This course is designed to provide a solid foundation in the principles of financial derivatives and risk management. It attempts to strike a balance between institutional details, theoretical foundations, and practical applications. The course equally emphasizes pricing and investment strategies in order to motivate students to start thinking about risk management in financial markets. Parallel to the already increasing attempts to integrate derivative securities and markets into the Turkish financial system, it is believed that this course will fill a gap and students will be exposed to a rather comprehensive coverage of theory and application in the derivatives area. This course is expected to give the students a “competitive advantage” when they enter the job market since “derivatives” is a “hot topic” nowadays and BA4825/5825/IAM520 is one of the very few courses offered on this topic in Turkey!
2. IAM 521 Financial Management (3-0)3
The objective of this course is to familiarize the students with the world of finance, viewed especially from a corporations angle. The technical objectives include teaching about a wide array of concepts ranging from the basics of risk, return, time value of money and valuation to the more advanced discussions of capital budgeting and capital structure. The conceptual objectives include creating awareness about the variety and complexity of the financial decisions that are faced by the manager of a corporation on a daily basis. Finally, the philosophical objectives include demonstrating how the world of finance can be fascinatingly interesting and surprisingly challenging in a rather enjoyable way!
3. IAM 524 Financial Economics (3-0)3
Competitive Models with Symmetric Information : Arbitrage and Martingales, Pricing and Hedging Contingent Claims, Consumption and Portfolio Decisions, Walrasian Equilibrium Theory and Term Structure of Interest Rates. Strategic Models with Asymmetric Information: Market Microstructure : A Critique of the Walrasian Equilibrium : The Informational Role of Prices, The Rational Expectations Equilibrium (REE) Concept and Problems, Noisy REE: Aggregation and Transmission of Information, Trading contraints and New Problems, Market Structure and Regulation, Asymmetric Information Models of Market Making, Homogeneous Information Models of Market Making, Intraday transaction Prices and Volumes.
4. IAM 526 Time Series Applied to Finance (3-0)3
This course is concerned with recent developments in the time series techniques for the analysis of financial markets. It provides a rigorous account of the time series techniques dealing with univariate and multivariate time series models. The techniques will be illustrated by a number of applications.
5. IAM 530 Elements of Probability and Statistics (3-0)3
The goal of this course is to introduce students to the basic probability theory and mathematical statistics and help them in establishing a good theoretical background for their future professions. This course provides a comprehensive introduction to probability, statistical theory and methodology. Lectures will explain the theoretical origins and practical implications of statistical formulae.
Content of this course: Probability, combinatorics, random variables, expectations, joint distribution functions, conditional distributions, distribution functions, moment generating functions, limit theorems, exponential families, sufficiency and completeness, point estimation, hypothesis testing, interval estimation, linear regression.
6. IAM 541 Probability Theory (3-0)3
The objective of this course is to initiate students to Probability Theory in which the main tools are those of Measure Theory. The proposed outline constitutes the prerequisites for Stochastic Calculus and other studies in the domain of stochastic processes.
The content of the course covers probability spaces, independence, conditional probability, product probability spaces, random variables and their distributions, distribution functions, mathematical expectation ( integration with respect to a probability measure), Lp-spaces, moments and generating functions, conditional expectation, linear estimation, Gaussian vectors, various convergence concepts, central limit theorem and laws of large numbers.
7. IAM 582 Life Insurance Mathematics (3-0)3
Theory of compound interest, future lifetimes, life tables, life insurance, annuities and premiums, reserves and expenses, multiple decrements, claim amount modelling, basics of the stochastic modelling for life insurance
Establish a fundamental knowledge of life insurance modelling and insurance fund anagement, developing skills in life insurance premium and reserve calculations
8. IAM 583 Pension Fund Modeling (3-0)3
Risk theory for pension funds. Pension schemes for active and retired lives.Valuation of pension plans. Funding Methods:Unit Credit, Attained Age, Entry Age Normal and other Methods.Contributory and Benefit Plans
9. IAM 584 Advanced Actuarial Mathematics (3-0)3
Developing knowledge and skills in actuarial analyses. Using probability and statistics,stochastic processes and advanced mathematical methods in actuarial model building and applications. Insurance models.Multiple life and multiple decrements theory.Actuarial risk.Population theory.Interest as a random variable.
10. IAM 746 Actuarial Risk Theory (3-0)3
Basic concepts of probability in connection with Risk Theory; introduction to risk processes (claim number process, claim amount process, total claim number process, total claim amount process, inter-occurance process); convolution and mixed type distributions; risk models (individual and collective risk models); numerical methods ( simple methods for discrete distributions, Edgeworth approximation, Esscher approximation, normal power approximation); premium calculation principles; Credibility Theory; retentions and reinsurance; Ruin Theory; ordering of risks.