. "Security And Privacy"@en . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . "Cryptography"@en . . "6" . "Description:\nBrief description of the course:\n1. Mathematics: boolean algebra, number theory, modular algebra, abstract algebra\n2. Historical cryptography: Caesar cipher, Vigenere cipher, transposition cipher, Affine cipher, main crypto-analytic techniques\n3. Theory of unbreakable (information-theoretically secure) ciphers: one-time pad, perfect secrecy, elements of probability theory\n4. Symmetric cryptography: stream ciphers, block ciphers, modes of operation\n5. Computability and Computational Complexity: Turing machine, computability, big O notation, Search-Decision problems\n6. The problem of key establishment: Public Key Cryptography, Diffie-Hellman key exchange, Man in the middle attack\n7. Limited Adversaries and Security: one-way functions, bit security, adversary models, security definitions\n8. The RSA cryptosystem: Description, properties, and security\n9. RSA Attacks and Implementation Failures: Description of several protocol weaknesses if the RSA is used in improper ways\n10. Probabilistic Encryption. ElGamal-type Cryptosystems: Probabilistic vs Deterministic Encryption, IND-CPA, IND-CCA\n11. Digital signatures and Hash functions: Definitions and security properties\n12. Identification schemes and Zero Knowledge proofs.\n13. Public Key infrastructure: certificates, ID-Card, Smart-ID, TLS\n14. Introduction to Post-Quantum and Esoteric Cryptography\nLearning outcomes:\nAfter completing this course, the student:\n- accurately uses standard cryptographic notation and terminology;\n- accurately recalls and explains cryptographic definitions from the topics covered during the course;\n- explains and analyses the most important symmetric cryptography and public key cryptography schemes;\n- solves practical problems that illustrate the usage of cryptographic primitives studied during the course;\n- identifies the security problems that arise in case of incorrect instantiation of cryptographic primitives studied during the course;\n- applies basic security definitions to analyse cryptographic primitives studied during the course;\n- identifies cryptographic algorithms that are suitable to solve simple security goals." . . "Presential"@en . "TRUE" . . "Master in Cybersecurity"@en . . "https://taltech.ee/en/masters-programmes/cybersecurity#p1817347" . "120"^^ . "Presential"@en . "The programme is taught jointly by the two largest public universities in Estonia. The Cybersecurity and Digital Forensics studies are concentrated in Tallinn, while the specialisation in Cryptography is concentrated in Tartu. Upon successful completion of the programme students will receive a joint degree signed by both universities - TalTech and the University of Tartu. \n- The public focus on the field of cyber security is growing around the world. Estonia is well known for its eagerness to put innovative IT solutions into everyday use. It is a pioneer in electronic identities and electronic voting and enthusiastically adopts mobile technology, online banking and electronic government services. However, with so many e-solutions and such extensive use of the internet, attention also needs to be turned to the security issue. By choosing electable courses, it is possible to specialise in one of the following aspects or a suitable mix of those:\n- Organisational aspects - law, organization, psychology, standards, etc.\n- Technological aspects - networking, attack/defence technology, cryptography.\n- Digital forensics is a branch of forensic science encompassing the recovery and investigation of material found in digital devices, often in relation to computer crime. The area is becoming critical for both data security and law enforcement and is involved in a complicated interplay between surveillance and counter-surveillance issues.\n- Cryptography is vital for the functioning of the modern interconnected world, since it is required to ensure privacy, data integrity, etc. Cryptography experts are required to develop new ways of keeping data secure, as well as making sure that the existing solutions are still strong enough. Study programme aims and objectives \nThe aim of the study program is to provide a broad background in cyber security, \nas well as the opportunity for in-depth study in the fields of Cybersecurity, Digital Forensics, or Cryptography. Students can focus their studies in technical, theoretical or organizational aspects or in a combination of those.\nA graduate of the program specializing in Cybersecurity is ready to be employed as a technical professional or a manager in the field of cybersecurity.\nA graduate of the program specializing in Digital Forensics is ready to be employed as a security incident handler in a company or a digital forensic expert in a law enforcement agency.\nA graduate of the program specializing in Cryptography is ready to be employed as a cybersecurity analyst.\nThe theoretical competence acquired is adequate for continuing studies as a Ph.D student."@en . . . "2"@en . "TRUE" . . "Master"@en . "Thesis" . "no tuition, other costs may apply" . "Euro"@en . "6000.00" . "Recommended" . "The programme conveys the specialist knowledge and professional skills needed on a career path leading to high-end technical roles (e.g. security analyst, architect or research engineer; security incident handler or a digital forensic expert in a law enforcement agency) or managerial roles (e.g. project/team leader or technology officer)."@en . "3"^^ . "TRUE" . "Midstream"@en . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .