Secure Systems Engineering
Prof. Sape J. Mullender (email@example.com)
The class of Secure Systems Engineering is intended for predoctoral
students in their final years, for doctoral students (AiO's and TwAiO's)
and for postacademic computer experts seeking to update their expertise
in computer security.
Class contents: introduction to cryptography, theory of authentication,
access control, security of the Internet, of Unix and of the systems commonly
used in industry, security of electronic payment systems, and securing
the human/computer interface.
The students will be required to give a presentation of the contents
of a published article pertaining to security. They will also carry out
a small literature survey and write a ten to fifteen-page essay.
The class will be taught in English, so that Dutch students will achieve
additional proficiency in using the language -- essential for their further
carreer -- and so that foreign students (many of the AiO's are foreign)
and post-academic students can make use of the course as well.
This schedule is subject to variation.
- December 11, 2000
Schneier Chapters 1 en 2
- December 18, 2000
Schneier Chapter 3
- January 15, 2001
- January 22, 2001
Logic of Authentication
- January 29, 2001
Logic of Authentication
Schneier Chapter 8, 10
- February 5, 2001
Schneier Chapters 11, 19
- February 12, 2001
Schneier Chapter 12
- February 19, 2001
Why Cryptosystems Fail
- February 26, 2001
Slides used during class
Chapter 1, Applied Cryptography
Chapter 2, Applied Cryptography
Chapter 3, Applied Cryptography
Chapter 8, Applied Cryptography
Chapter 11, Applied Cryptography
Chapter 12, Applied Cryptography
Chapter 19, Applied Cryptography
Chapter 20, Distributed Systems
Chapter 21, Distributed Systems
A Logic of Authentication
Find out about, and give an overview of tamperproof smart cards. Discuss
techniques for making smart cards tamperproof and methods of attack.
Give an overview of the state of the art in smart card operating systems.
Discuss the security that can be provided by Internet Firewalls (see,
for instance, [Cheswick and Bellovin]) (Bas)
Give an overview of Phil Zimmermann's PGP, discuss merits and defects.
Give an overview of Ssh, how it works, what standards it uses; discuss
merits and defects. (Jeroen)
Analyse the virus phenomenon: Why are computers running Windows so
much more prone to attacks than those running Unix? What sort of
security measures can one take against virus attacks?
Give an overview of digital watermark technology. How can they be used
to protyect digital images, sound, movies? What protection do they provide?
How do the work?
Give an overview of David Chaum's anonymous payment system, how it works and
what it achieves. (Joost)
How does security work in NEtscape and Internet Explorer? How secure
is it? Against what attacks does it or does it not protect? (Richard)
|Chapters 1, 2, 3, 8, 9, 10, 12
and Sections 6.1, 6.4, 11.1-11.5, 19.1-19.3
John Wiley & Sons, Inc, 1996
|Chapters 20 and 21 of
||Distributed Systems, 2nd edition,
Sape J. Mullender, editor
ACM Press, 1993
Communications of the ACM 37(11)
||A Logic of Authentication
Michael Burrows, Martin Abadi, and Roger Needham
SRC Technical Report 39
||Prudent Engineering Practice for Cryptographic Protocols
Martin Abadi and Roger Needham
SRC Technical Report 125
Ross Anderson's article,
`Robustness Principles for Public Key Protocols' and many of the others
on his home page.
Edward Amoroso, Fundamentals of Computer Security Technology,
Prentice Hall, Englewood Cliffs, ISBN 0-13-108929-3
Other interesting chapters in Schneier's book are: 5, 6, 7,13, 14, 15,
24 and 25
Firewalls and Internet Security, by William R. Cheswick and Steven
M. Bellovin, Addison-Wesley, 1994, ISBN 0-201-63357-4