Distributed Computing
ETH Zurich

Discrete Event Systems (HS 2024)

Over the past few decades the rapid evolution of computing, communication, and information technologies has brought about the proliferation of new dynamic systems. A significant part of activity in these systems is governed by operational rules designed by humans. The dynamics of these systems are characterized by asynchronous occurrences of discrete events, some controlled (e.g. hitting a keyboard key, sending a message), some not (e.g. spontaneous failure, packet loss).

The mathematical arsenal centered around differential equations that has been employed in systems engineering to model and study processes governed by the laws of nature is often inadequate or inappropriate for discrete event systems. The challenge is to develop new modeling frameworks, analysis techniques, design tools, testing methods, and optimization processes for this new generation of systems.

In this lecture we give an introduction to discrete event systems. We start out the course by exploring the limits of what is computable and what is not. In doing so, we will consider three distinct models of computation which are often used to model discrete event systems: finite automata, push-down automata and Turing machines (ranked in terms of expressiveness power). In the second part of the course we analyze discrete event systems. We first examine discrete event systems from an average-case perspective: we model discrete events as stochastic processes, and then apply continuous time markov chains and queueing theory for an understanding of the typical behavior of a system. Then we analyze discrete event systems from a worst-case perspective using the theory of online algorithms and adversarial queueing. In the last part of the course we introduce methods that allow to formally verify certain properties of Finite Automata and Petri Nets. These are some typical analysis questions we will look at: Do two given systems behave the same? Does a given system behave as intended? Does the system eventually enter a dangerous state?

Course language: English

Lecture by Prof. Lana Josipović, Prof. Laurent Vanbever, and Prof. Barbara Keller (standing in for Prof. Roger Wattenhofer), Thursday 14.15-16.00 @ HG D 7.2, starting 19.09.2024.

Exercises by Borna Šimić, Frédéric Berdoz, Roland Schmid, and Jiahui Xu, Thursday 16.15-17.45 @ HG D 7.2.


News

01.09.2024Welcome to the new semester!
17.10.2024Finalized contents for the first part of the course (given by Prof. Vanbever) and updated the exam information, thank you all for participating!

Exercise Proceedings

At the beginning of every lecture week, we will publish a new exercise sheet here. This exercise sheet is intended to be solved during the exercise session on Thursday where tutors will be available to assist you and to answer potential questions. The exercises often require information from the lecture notes, so please make sure that you have them available in some way.

You can hand in your solutions for correction after the exercise session on a voluntary basis. But this is not mandatory or required to be admitted to the exam.

Lecture Material

Chapter Title Lecturer Lecture Notes Exercises Responsible Assistant Additional Material
Chapter 0 Introduction
19.09.2024
Laurent Vanbever PDF 1:1
PDF 4:1
--- --- ---
Chapter 1 Regular Languages
19.09.2024 – 26.09.2024
Laurent Vanbever PDF 1:1
PDF 4:1
Exercise 1
Slides 1
Solution 1

Exercise 2
Slides 2
Solution 2
Roland Schmid Lecture 1 Recording (HS20)



Lecture 2 Introduction & Recap Slides
Lecture 2 Recording (HS20)
Chapter 2 Non-Regular Languages
03.10.2024 – 17.10.2024
Laurent Vanbever PDF 1:1
PDF 4:1
Exercise 3
Slides 3
Solution 3

Exercise 4
Slides 4
Solution 4

Exercise 5
Slides 5
Solution 5
Roland Schmid Lecture 3 Introduction & Recap Slides
Lecture 3 Recording (HS20)


Lecture 4 Introduction & Recap Slides
Lecture 4 Recording (HS20)


Lecture 5 Introduction & Recap Slides
Lecture 5 Recording (HS20)
relevant up to 1:11h
Example: Tandem-Pumping Lemma (HS20)
Chapter 3 Markov Chains
24.10.2024
Barbara Keller PDF 1:1 Exercise 6
Solution 6
Frédéric Berdoz Lecture Recording (HS20)
Exercise Recording (HS20)
Chapter 4 Queueing
31.10.2024 - 7.11.2024
Barbara Keller PDF 1:1 Exercise 7
Solution 7

Exercise 8
Solution 8
Borna Šimić Lecture Recording (HS20)
Exercise Recording (HS20)

Lecture Recording 2 (HS20)
Exercise Recording 2 (HS20)
Chapter 5 Online
14.11.2024 - 21.11.2024
Barbara Keller
PDF 1:1 Exercise 9
Solution 9

Exercise 10
Solution 10
Frédéric Berdoz


Borna Šimić
Lecture Recording (HS20)
Exercise Recording (HS20)

Lecture Recording 2 (HS20)
Exercise Recording 2 (HS20)
Chapter 6 Verification of Finite Automata
28.11.2024 - 05.12.2024
Lana Josipović PDF(1) 1:1


PDF(2) 1:1
Exercise 11 Solution 11

Exercise 12 Solution 12
Jiahui Xu Lecture Recording(1) (HS22)
Exercise Recording (HS21)

Lecture Recording(2) (HS22)
Chapter 7 Petri Nets
12.12.2024 - 19.12.2024

🎄🎁
Lana Josipović PDF(1) 1:1


PDF(2) 1:1 PDF(3) 1:1
Exercise 13
Solution 13

Exercise 14
Jiahui Xu

Exam

Regarding the first part of the course (given by Prof. Vanbever), all material covered in the lecture and the exercises can be prospects for the examination as usual. Note that transducers and turing machines (covered in the recordings from HS20) are not relevant for this year's exam.

Old Exams

If you are already thinking about the exam, or would like some more exercises, you can also have a look at older exams (some with solutions):

Please keep in mind that the content of the lecture has been updated a few times in recent years, especially the third part, which is being taught by a new lecturer! Therefore, some of the material from the old exams might no longer be covered in the current lecture and additional material has been added.


References

[bertsekas] Data Networks
Dimitri Bertsekas, Robert Gallager.
Prentice Hall, 1991, ISBN: 0132009161
[borodin] Online Computation and Competitive Analysis
Allan Borodin, Ran El-Yaniv.
Cambridge University Press, 1998
[burch] Symbolic Model Checking
Burch, J. R. and Clarke, E. M. and McMillan, K. L. and Dill, D. L. and Hwang, L. J.
Inf. Comput. 98, 2 (June 1992), pp. 142-170
Download
[cassandras] Introduction to Discrete Event Systems
Christos Cassandras, Stephane Lafortune.
Kluwer Academic Publishers, 1999, ISBN 0-7923-8609-4
[exorciser] Exorciser - Interaktive Lernsoftware für theoretische Informatik
Download
[fiat] Online Algorithms: The State of the Art
A. Fiat and G. Woeginger.
[hochbaum] Approximation Algorithms for NP-hard Problems (Chapter 13 by S. Irani, A. Karlin)
D. Hochbaum.
[murata] Petri Nets: Properties, Analysis and Applications
Tadao Murata.
Proceedings of the IEEE, vol. 99, issue 4, April 1989. pp. 541--580
Download
[schickinger] Diskrete Strukturen (Band 2: Wahrscheinlichkeitstheorie und Statistik)
T. Schickinger, A. Steger.
Springer, Berlin, 2001
[sipser] Introduction to the Theory of Computation
Michael Sipser.
PWS Publishing Company, 1996, ISBN 053494728X