Stochastic Processes (MAE532): Διαφορά μεταξύ των αναθεωρήσεων
Χωρίς σύνοψη επεξεργασίας |
Χωρίς σύνοψη επεξεργασίας |
||
(Μία ενδιάμεση αναθεώρηση από τον ίδιο χρήστη δεν εμφανίζεται) | |||
Γραμμή 1: | Γραμμή 1: | ||
* [[Στοχαστικές Διαδικασίες (ΜΑΕ532)|Ελληνική Έκδοση]] | * [[Στοχαστικές Διαδικασίες (ΜΑΕ532)|Ελληνική Έκδοση]] | ||
{{Course-UnderGraduate-Top-EN}} | |||
{{Menu-OnAllPages-EN}} | |||
=== General === | === General === |
Τελευταία αναθεώρηση της 12:25, 15 Ιουνίου 2023
- Ελληνική Έκδοση
- Undergraduate Courses Outlines
- Outline Modification (available only for faculty members)
- Department of Mathematics
- Save as PDF or Print (to save as PDF, pick the corresponding option from the list of printers, located in the window which will popup)
General
School |
School of Science |
---|---|
Academic Unit |
Department of Mathematics |
Level of Studies |
Undergraduate |
Course Code |
ΜΑΕ532 |
Semester |
5 |
Course Title |
Stochastic Processes |
Independent Teaching Activities |
Lectures (Weekly Teaching Hours: 3, Credits: 6) |
Course Type |
Special Background |
Prerequisite Courses | - |
Language of Instruction and Examinations |
Greek |
Is the Course Offered to Erasmus Students |
Yes (in English, reading Course) |
Course Website (URL) | See eCourse, the Learning Management System maintained by the University of Ioannina. |
Learning Outcomes
Learning outcomes |
The term "stochastic" is used to describe phenomena in which some randomness inherent. A stochastic process is a probabilistic model that describes the behaviour of a system that randomly evolves over time. Observing the system at discrete points in time (for instance at the end of each day or at the end of a time period, etc.) one gets a discrete time stochastic process. Observing the system continuously through time one gets a continuous time stochastic process. Objectives of the course are:
The student should be able to understand the meaning of the stochastic process, use the Markov processes for modelling systems and become familiar with their application, and be able to make various calculations and appropriate conclusions when the stochastic process describes a specific applied problem. |
---|---|
General Competences |
|
Syllabus
Random Walk: Simple random walk, absorbing barriers, reflecting barriers. Markov Chains: General definitions, classification of states, limit theorems, irreducible chains. Markov Processes: The birth-death process. Applications.
Teaching and Learning Methods - Evaluation
Delivery |
Classroom (face-to-face) | ||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|
Use of Information and Communications Technology | -
Use of ICT in communication with students | ||||||||||
Teaching Methods |
| ||||||||||
Student Performance Evaluation |
Final written exam in Greek (in case of Erasmus students in English) which concentrates on the solution of problems which are motivated by the main themes of the course. |
Attached Bibliography
See the official Eudoxus site or the local repository of Eudoxus lists per academic year, which is maintained by the Department of Mathematics. Books and other resources, not provided by Eudoxus:
- R. Dobrow. Introduction to Stochastic Processes with R, Wiley, 2016.
- R. Durret. Essentials of Stochastic Processes, Springer, 3rd edition, 2016.
- V.G. Kulkarni. Modeling and Analysis of Stochastic Systems, 3rd edition, CRC Press, London 2017.
- N. Privault. Understanding Markov Chains [electronic resource] HEAL-Link Springer ebooks, 2013 (Κωδικός Εύδοξου: 73260010).
- M. Pinksy, S. Karlin. An introduction to stochastic modelling, 4th edition, Academic Press, 2011.
- S. Ross. Introduction to probability models, Academic Press, New York, 2014.
- [Περιοδικό / Journal] Stochastic Processes and their Applications (Elsevier)
- [Περιοδικό / Journal] Stochastics (Taylor - Francis)
- [Περιοδικό / Journal] Journal of Applied Probability (Cambridge University Press)