250111 VO Topics in Algebra: Cryptography (2024S)
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An/Abmeldung
Hinweis: Ihr Anmeldezeitpunkt innerhalb der Frist hat keine Auswirkungen auf die Platzvergabe (kein "first come, first served").
Details
Sprache: Englisch
Prüfungstermine
- Mittwoch 26.06.2024 08:00 - 18:15 Seminarraum 13 Oskar-Morgenstern-Platz 1 2.Stock
- Mittwoch 03.07.2024
- Freitag 05.07.2024
- Montag 08.07.2024
- Mittwoch 09.10.2024 08:00 - 18:15 Seminarraum 1 Oskar-Morgenstern-Platz 1 Erdgeschoß
- Donnerstag 14.11.2024 08:00 - 18:15 Seminarraum 4 Oskar-Morgenstern-Platz 1 1.Stock
Lehrende
Termine (iCal) - nächster Termin ist mit N markiert
- Dienstag 05.03. 09:45 - 11:15 Seminarraum 11 Oskar-Morgenstern-Platz 1 2.Stock
- Dienstag 19.03. 09:45 - 11:15 Seminarraum 11 Oskar-Morgenstern-Platz 1 2.Stock
- Dienstag 09.04. 09:45 - 11:15 Seminarraum 11 Oskar-Morgenstern-Platz 1 2.Stock
- Dienstag 16.04. 09:45 - 11:15 Seminarraum 11 Oskar-Morgenstern-Platz 1 2.Stock
- Dienstag 23.04. 09:45 - 11:15 Seminarraum 11 Oskar-Morgenstern-Platz 1 2.Stock
- Dienstag 30.04. 09:45 - 11:15 Seminarraum 11 Oskar-Morgenstern-Platz 1 2.Stock
- Dienstag 07.05. 09:45 - 11:15 Seminarraum 11 Oskar-Morgenstern-Platz 1 2.Stock
- Dienstag 14.05. 09:45 - 11:15 Seminarraum 11 Oskar-Morgenstern-Platz 1 2.Stock
- Dienstag 21.05. 09:45 - 11:15 Seminarraum 11 Oskar-Morgenstern-Platz 1 2.Stock
- Dienstag 28.05. 09:45 - 11:15 Seminarraum 11 Oskar-Morgenstern-Platz 1 2.Stock
- Dienstag 04.06. 09:45 - 11:15 Seminarraum 11 Oskar-Morgenstern-Platz 1 2.Stock
- Dienstag 11.06. 09:45 - 11:15 Seminarraum 11 Oskar-Morgenstern-Platz 1 2.Stock
- Dienstag 18.06. 09:45 - 11:15 Seminarraum 11 Oskar-Morgenstern-Platz 1 2.Stock
- Dienstag 25.06. 09:45 - 11:15 Seminarraum 11 Oskar-Morgenstern-Platz 1 2.Stock
Information
Ziele, Inhalte und Methode der Lehrveranstaltung
This introductory course is on selected chapters of modern cryptography. We discuss both classical and rather recent cryptographic topics. These include currently the most popular RSA (= Rivest-Shamir-Adleman) and ECC (= Elliptic Curve Cryptography) public-key cryptosystems as well as the use of cryptography in blockchain technology. Theoretical results are supported by exercises and concrete real-life examples such as the discussion on security issues in messengers and in the design of Bitcoin.
Art der Leistungskontrolle und erlaubte Hilfsmittel
Oral exam or written manuscript. The choice is to make at the beginning of the course.
Mindestanforderungen und Beurteilungsmaßstab
The knowledge of the following fundamental concepts is required: groups, vector spaces, linear transformations, basics in number theory and probability.
Prüfungsstoff
Content of the lectures and exercises.Exam questions:
(1) Cryptography principles: definitions, (non)-examples. Basic cryptography concepts (primitive, protocol, cover time, etc.). Basic model for secrecy: (non)- examples. Cryptosystem for secrecy: definition, examples. Symmetric versus asymmetric cryptosystems.
(2) Main attacks on encryption algorithms. Passive versus active attacks. Keys: length, size. Brute-force attack: assumptions, estimates on key lengths.
(3) Examples of symmetric cryptosystems: Caesar and Substitution ciphers. The letter frequency analysis. Monoalphabetic and polyalphabetic ciphers. Vigenère cipher. If the given key of a Vigenère Cipher has repeated letters, does it make it any easier to break?
(4) The computational complexity of basic mathematical operations and of the exhaustive key search attack. Complexity classes of algorithms.
(5) Three types of security. Perfect secrecy: definition, examples, equivalent formulations (with proof). Perfect secrecy: Shannon’s Theorem (with proof).
(6) RSA cryptosystem: definition, examples, correctness (encryption and decryption are inverse operations). Parameter generation, its complexity. Main attacks.
(7) One-way function, with a trapdoor. Theorem: RSA keys vs Factoring (formulation and sketch of proof).
(8) Hash function: definition, types of resistance, (non)-examples. Optimal asymmetric encryption padding.
(9) Discrete logarithm problem. The DLP assumption. The DLP in (Z/(p-1)Z, +) Is breaking the ECC cryptosystem equivalent to solving the DLP?
(10) ElGamal cryptosystem and parameter generation: definition, correctness (encryption and decryption are inverse operations). Theorem: ElGamal keys versus DLP (with proof).
(11) Elliptic curve: definition, singularities, normal forms, tangents. Theorem: the intersection of E with a projective line (with proof).
(12) Group structure on the elliptic curve over the algebraic closure, geometrically: definition and theorem (with proof).
(13) Cayley-Bacharach’s theorem (with proof).
(14) Associativity (sketch of proof).
(15) Elliptic curves over finite fields: theorems (without proof) and examples. Check that for a prime q, each natural number in the Hasse interval occurs as the order of the elliptic curve group over the field of q elements.
(16) Diffie-Hellman key agreement: protocol, attacks. The DHP problem. The ECDHE.
(17) Digital Signature Scheme. RSA signature algorithm. Attacks: definitions and examples.
(18) DSS with hashing. Hash functions from block ciphers: definition and example, with proof (the example where (x,y)àaxby).
(19) DSS and Public-key cryptosystem: sign-then-encrypt versus encrypt-versus- sign.
(20) ElGamal variant of DSS: definition and correctness. Security assumptions. Example of misuse (with proof).
(21) ElGamal variant of DSS: example of misuse (with proof). ECDSA: definition and correctness.
(22) Digital currency: definition and security requirements. Distributed ledgers. Blockchain. Security assumptions underlying the generation of the bitcoin address.
(23) Bitcoin transaction and its verification. Merkle tree. Bitcoin mining.
(24) Bit generator. Linear feedback shift register: definition, periods, security. RSA bit generator.
(25) Distinguisher. Next bit predictor. Yao’s theorem (sketch of proof).
(26) Error-correcting codes and expander graphs.
(27) Describe the probabilistic pigeonhole principle and explain, with examples, why it is relevant in cryptography (i.e hash functions, birthday paradox, etc).
(28) Describe a variety of attacks that rely on structural weaknesses in respective cryptosystems (for instance, known message attacks for multiplicative systems, or weaknesses of El Gamal under weak random choices).
(29) Describe Shanks algorithm, give examples of its use and outline how to use Shanks Algorithm to compute the order of an elliptic curve of prime order in combination with Hasse’s bound.
(1) Cryptography principles: definitions, (non)-examples. Basic cryptography concepts (primitive, protocol, cover time, etc.). Basic model for secrecy: (non)- examples. Cryptosystem for secrecy: definition, examples. Symmetric versus asymmetric cryptosystems.
(2) Main attacks on encryption algorithms. Passive versus active attacks. Keys: length, size. Brute-force attack: assumptions, estimates on key lengths.
(3) Examples of symmetric cryptosystems: Caesar and Substitution ciphers. The letter frequency analysis. Monoalphabetic and polyalphabetic ciphers. Vigenère cipher. If the given key of a Vigenère Cipher has repeated letters, does it make it any easier to break?
(4) The computational complexity of basic mathematical operations and of the exhaustive key search attack. Complexity classes of algorithms.
(5) Three types of security. Perfect secrecy: definition, examples, equivalent formulations (with proof). Perfect secrecy: Shannon’s Theorem (with proof).
(6) RSA cryptosystem: definition, examples, correctness (encryption and decryption are inverse operations). Parameter generation, its complexity. Main attacks.
(7) One-way function, with a trapdoor. Theorem: RSA keys vs Factoring (formulation and sketch of proof).
(8) Hash function: definition, types of resistance, (non)-examples. Optimal asymmetric encryption padding.
(9) Discrete logarithm problem. The DLP assumption. The DLP in (Z/(p-1)Z, +) Is breaking the ECC cryptosystem equivalent to solving the DLP?
(10) ElGamal cryptosystem and parameter generation: definition, correctness (encryption and decryption are inverse operations). Theorem: ElGamal keys versus DLP (with proof).
(11) Elliptic curve: definition, singularities, normal forms, tangents. Theorem: the intersection of E with a projective line (with proof).
(12) Group structure on the elliptic curve over the algebraic closure, geometrically: definition and theorem (with proof).
(13) Cayley-Bacharach’s theorem (with proof).
(14) Associativity (sketch of proof).
(15) Elliptic curves over finite fields: theorems (without proof) and examples. Check that for a prime q, each natural number in the Hasse interval occurs as the order of the elliptic curve group over the field of q elements.
(16) Diffie-Hellman key agreement: protocol, attacks. The DHP problem. The ECDHE.
(17) Digital Signature Scheme. RSA signature algorithm. Attacks: definitions and examples.
(18) DSS with hashing. Hash functions from block ciphers: definition and example, with proof (the example where (x,y)àaxby).
(19) DSS and Public-key cryptosystem: sign-then-encrypt versus encrypt-versus- sign.
(20) ElGamal variant of DSS: definition and correctness. Security assumptions. Example of misuse (with proof).
(21) ElGamal variant of DSS: example of misuse (with proof). ECDSA: definition and correctness.
(22) Digital currency: definition and security requirements. Distributed ledgers. Blockchain. Security assumptions underlying the generation of the bitcoin address.
(23) Bitcoin transaction and its verification. Merkle tree. Bitcoin mining.
(24) Bit generator. Linear feedback shift register: definition, periods, security. RSA bit generator.
(25) Distinguisher. Next bit predictor. Yao’s theorem (sketch of proof).
(26) Error-correcting codes and expander graphs.
(27) Describe the probabilistic pigeonhole principle and explain, with examples, why it is relevant in cryptography (i.e hash functions, birthday paradox, etc).
(28) Describe a variety of attacks that rely on structural weaknesses in respective cryptosystems (for instance, known message attacks for multiplicative systems, or weaknesses of El Gamal under weak random choices).
(29) Describe Shanks algorithm, give examples of its use and outline how to use Shanks Algorithm to compute the order of an elliptic curve of prime order in combination with Hasse’s bound.
Literatur
1. Martin, Keith M. Everyday cryptography. Fundamental principles and applications. Second edition. Oxford University Press, Oxford, 2017. xxx+674 pp. ISBN: 978-0-19-878801-0; 978-0-19-878800-3
2. Stinson, Douglas R. Cryptography. Theory and practice. Third edition. Discrete Mathematics and its Applications (Boca Raton). Chapman & Hall/CRC, Boca Raton, FL, 2006. xviii+593 pp. ISBN: 978-1-58488-508-5; 1-58488-508-4
3. Daniel J. Bernstein & Tanja Lange, Post-quantum cryptography, Nature, 2017, Vol.549, 188–194. ISSN: 0028-0836 ; E-ISSN: 1476-4687 ; DOI: 10.1038/nature23461
2. Stinson, Douglas R. Cryptography. Theory and practice. Third edition. Discrete Mathematics and its Applications (Boca Raton). Chapman & Hall/CRC, Boca Raton, FL, 2006. xviii+593 pp. ISBN: 978-1-58488-508-5; 1-58488-508-4
3. Daniel J. Bernstein & Tanja Lange, Post-quantum cryptography, Nature, 2017, Vol.549, 188–194. ISSN: 0028-0836 ; E-ISSN: 1476-4687 ; DOI: 10.1038/nature23461
Zuordnung im Vorlesungsverzeichnis
MALV, MAMV
Letzte Änderung: Di 15.10.2024 11:26