Short Title:Secure Communication & Cryptography
Full Title:Secure Communication & Cryptography
Module Code:MIOT H6016
 
ECTS credits: 5
NFQ Level:9
Module Delivered in 1 programme(s)
Module Contributor:Mark Cummins
Module Description:The purpose of this module is to allow learners identify vulnerabilities in data communication systems and analyse and evaluate the different types of encryption and security processes available. The module with teach and demonstrate how to secure data communications systems.
Learning Outcomes:
On successful completion of this module the learner will be able to
  1. Analyse and evaluate the different types of encryption and security processes available
  2. Identify vulnerabilities in data communication systems
  3. Assess vulnerabilities in systems and identify limitations to the application of each technology
 

Module Content & Assessment

Indicative Content
Role of secure communications in society
Review of communication applications: Users and needs, Nature and limitations of secure communication , Types of security threats, secure applications, threats, risk assessment, authentication protocols, hashing, random numbers, evolution of cryptography and going forward.
Threats and Security Management
Technical threats to communication security, authentication, confidentiality, integrity (data signatures), availability (PINs, passwords, biometrics, challenge-response control, tamper proof systems. Cipher Algorithms and Key management.
Secure Communication
Threat models, Applied Crypto, Principles, ciphers, pseudo-randomness, encryption schemes. Hashing, One Way Functions and Commitment, Authentication and shared key distribution, Public Key Cryptography, Public Key Digital Signatures, Public Key Infrastructure (PKI), Web and Transaction Layer Security (TLS & SSL), Internet Layer/Protocol security (IP-sec), Denial-Of-Service and Intrusions Attacks on Hosts and Networks, Secure E-Commerce Applications: Copyright Protection. Secure email and Virtual Private Networks.
Cryptography
Overview of Cryptography, Privacy, Mathematical Overview, Transposition and Substitution Ciphers, Block Ciphers, Public Key Systems, RSA System, Key Management, Digital Signatures and Authentication, Stream Ciphers.
Indicative Assessment Breakdown%
Course Work Assessment %50.00%
Final Exam Assessment %50.00%
Course Work Assessment %
Assessment Type Assessment Description Outcome addressed % of total Assessment Date
Project Research and evaluate an existing solution for secure communications 1 20.00 Week 6
Project Analyse and assess a given secure communication solution 2,3 30.00 Week 11
Final Exam Assessment %
Assessment Type Assessment Description Outcome addressed % of total Assessment Date
Formal Exam End-of-Semester Final Examination 1,2,3 50.00 End-of-Semester
Indicative Reassessment Requirement
Repeat examination
Reassessment of this module will consist of a repeat examination. It is possible that there will also be a requirement to be reassessed in a coursework element.

ITB reserves the right to alter the nature and timings of assessment

 

Indicative Module Workload & Resources

Indicative Workload: Full Time
Frequency Indicative Average Weekly Learner Workload
Every Week 60.00
Every Week 65.00
Resources
Recommended Book Resources
  • Richard E. Blahut 2014, Cryptography and Secure Communication, 1 Ed., Cambridge University Press [ISBN: 978-110701427]
  • Douglas R. Stinson 2001, Cryptography: Theory and Practic, CRC Press
  • Keith M. Martin 2012, Everyday Cryptography: Fundamental Principles and Applications, 1 Ed., Oxford University Press [ISBN: 978-01996955]
  • Jonathan Katz 2014, Introduction to Modern Cryptography, 2 Ed., Chapman and Hall/CRC [ISBN: 978-146657026]
  • B. Schneier 1996, Applied Cryptography, 2 Ed., Wiley
Supplementary Book Resources
  • Alfred J. Menezes, Paul C. van Oorschot and Scott A. Vanstone 1996, Handbook of Applied Cryptography, CRC Press
This module does not have any article/paper resources
Other Resources

Module Delivered in

Programme Code Programme Semester Delivery
BN_EMIOT_R Master of Engineering in Internet of Things Technologies [BN535R 60 credits taught with a 30 credit research project] 2 Mandatory