Postgraduate taught 

Financial Risk Management MSc

Applied Computational Finance ECON5065

  • Academic Session: 2020-21
  • School: Adam Smith Business School
  • Credits: 20
  • Level: Level 5 (SCQF level 11)
  • Typically Offered: Semester 2
  • Available to Visiting Students: No
  • Available to Erasmus Students: No

Short Description

Many problems in economics, finance and financial engineering do not possess a closed-form solution which could be computed easily. Typically, these problems are solved by using numerical algorithms and simulation methods. This course covers the study and implementation of such techniques. These include Monte Carlo simulation for pricing complex derivatives; finite difference methods to solve partial differential equations for option pricing; effective methods to compute hedging strategies; numerical dynamic programming for optimal portfolios, resource management and economic growth. Advanced understanding of these techniques and their implementation on computer using software packages and programming languages is the focus of this course.


One two-hour lecture per week for 10 weeks.

Ten one-hour computer labs.

Excluded Courses



Mathematical Finance (ECON5020)


■ Group Coursework: Group computer project (30% of final grade for course)

■ Online quizzes: four online quiz (40% of final grade for course)

■ Examination: two-hour end-of-course examination (30% of final grade for course)

Main Assessment In: April/May

Course Aims

The main aim of this course is to introduce students to core techniques in computational finance, such as simulation of asset prices, pricing options using stochastic models, Monte Carlo methods as applied to complex derivatives, solving Black-Scholes type equations numerically, solving dynamic optimization problems numerically, and how to implement these techniques using modelling software packages and programming languages.

Intended Learning Outcomes of Course

By the end of this course students will be able to:


1. Calculate the price and hedging portfolios of complex derivatives using Monte Carlo simulations 

2. Calculate the price of American and other exotic options by implementing numerical methods to solve the related partial differential equations

3. Implement dynamic programming algorithms to solve problems in portfolio optimisation, resource management and monetary policy

4. Demonstrate advanced skills in modelling software packages and programming languages

Minimum Requirement for Award of Credits

Students must submit at least 75% by weight of the components (including quizzes and examination) of the course's summative assessment.