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ST227      Half Unit
Survival Models

This information is for the 2022/23 session.

Teacher responsible

Mr Georgios Zouros

Availability

This course is compulsory on the BSc in Actuarial Science. This course is available on the BSc in Business Mathematics and Statistics, BSc in Data Science and BSc in Mathematics, Statistics and Business. This course is available as an outside option to students on other programmes where regulations permit and to General Course students.

Pre-requisites

Students must have completed Mathematical Methods (MA100) and Elementary Statistical Theory (ST102).

“Students must have completed one of the following two combinations of courses: (a) ST102 and MA100, or (b) MA107 and ST109 and EC1C1. Equivalent combinations may be accepted at the lecturer’s discretion.”

Course content

An introduction to stochastic processes with emphasis on life history analysis and actuarial applications. Principles of modelling; model selection, calibration, and testing; Stochastic processes and their classification into different types by time space, state space, and distributional properties; construction of stochastic processes from finite-dimensional distributions, processes with independent increments, Poisson processes and renewal processes and their applications in general insurance and risk theory, Markov processes, Markov chains and their applications in life insurance and general insurance, extensions to more general intensity-driven processes, counting processes, semi-Markov processes, stationary distributions. Determining transition probabilities and other conditional probabilities and expected values; Integral expressions, Kolmogorov differential equations, numerical solutions, simulation techniques. Survival models - the random life length approach and the Markov chain approach; survival function, conditional survival function, mortality intensity, some commonly used mortality laws. Statistical inference for life history data; Maximum likelihood estimation for parametric models, non-parametric methods (Kaplan-Meier and Nelson-Aalen), regression models for intensities including the semi-parametric Cox model and partial likelihood estimation; Various forms of censoring; The technique of occurrence-exposure rates and analytic graduation; Impact of the censoring scheme on the distribution of the estimators; Confidence regions and hypothesis testing.

Teaching

 

This course will be delivered through a combination of classes and lectures totalling a minimum of 35 hours across This year, some of this teaching may be delivered through a combination of virtual classes and flipped-lectures delivered as short online videos. This course includes a reading week in Week 6 of Michaelmas/Lent Term.

Students on this course will have a reading week in week 6 where they will be given review exercises to work on based on the first 5 weeks of the course. Also, students will be given a 10% coursework in R to work on within 24 hours in week 11 based on the material covered in the computer workshops which will run in weeks 5,7,8,9 and 10.

Formative coursework

Compulsory written answers to two sets of problems.

Indicative reading

S Ross, Stochastic Processes; R Norberg, Risk and Stochastics in Life Insurance; The Institute of Actuaries, CS2: Risk Modelling and Survival Analysis. For full details of the syllabus of CT4, see https://www.actuaries.org.uk/curriculum_entity/curriculum_entity/8.




Assessment

Exam (90%, duration: 3 hours) in the summer exam period.
Coursework (10%) in the LT Week 11.


Student performance results

(2019/20 - 2021/22 combined)

Classification % of students
First 70.6
2:1 17.5
2:2 7.6
Third 2.8
Fail 1.5

Key facts

Department: Statistics

Total students 2021/22: 134

Average class size 2021/22: 27

Capped 2021/22: Yes (130)

Lecture capture used 2021/22: Yes (LT)

Value: Half Unit

Course selection videos

Some departments have produced short videos to introduce their courses. Please refer to the course selection videos index page for further information.

Personal development skills

  • Leadership
  • Team working
  • Problem solving
  • Application of numeracy skills
  • Specialist skills