Chapter 1 Cryptography and Network Security Overview + 2024 PDF

Summary

This document is a lecture on cryptography and network security overview for 2024. It covers topics like cryptographic algorithms, mutual trust, and standards organizations. The author is Dr. Khader M. Al Titi from INU's Cyber Security Department.

Full Transcript

Chapter 1
Cryptography and
Network Security
Overview +
2024

Dr. Khader M. Al Titi
INU- Cyber Security Dept.
 – Reader’s Guide

The art of war teaches us to rely not on the
likelihood of the enemy's not coming, but
on our own readiness to receive him; not
on the chance of his not attacking, but
rather on the fact that we have made our
position unassailable.
—The Art of War, Sun Tzu
 Roadmap
Cryptographic algorithms
⚫ symmetric ciphers
⚫ asymmetric encryption
⚫ hash functions
MutualTrust
Network Security
Computer Security
 Standards Organizations
National Institute of Standards &
Technology (NIST)
Internet Society (ISOC)
International Telecommunication Union
Telecommunication Standardization Sector
(ITU-T)
International Organization for
Standardization (ISO)
RSA Labs (de facto)
 Chapter 1 – Introduction

The combination of space, time, and
strength that must be considered as the
basic elements of this theory of defense
makes this a fairly complicated matter.
Consequently, it is not easy to find a fixed
point of departure..
— On War, Carl Von Clausewitz
 Computer Security
theprotection afforded to an automated
information system in order to attain the
applicable objectives of preserving the
integrity, availability and confidentiality of
information system resources (includes
hardware, software, firmware,
information/data, and telecommunications)
Key Security Concepts
 Levels of Impact
candefine 3 levels of impact from a
security breach
⚫ Low
⚫ Moderate
⚫ High
 Low Impact
The loss could be expected to have a limited adverse
effect on organizational operations, organizational
assets, or individuals.
A limited adverse effect means that, for example, the
loss of confidentiality, integrity, or availability might
⚫ (i) cause a degradation in mission capability to an

extent and duration that the organization is able to
perform its primary functions, but the effectiveness of
the functions is noticeably reduced;
⚫ (ii) result in minor damage to organizational assets;

⚫ (iii) result in minor financial loss; or

⚫ (iv) result in minor harm to individuals.
 Moderate Impact
The loss could be expected to have a serious adverse effect
on organizational operations, assets, or individuals.
A serious adverse effect means that, e.g., the loss might
⚫ (i) cause a significant degradation in mission capability to

an extent and duration that the organization is able to
perform its primary functions, but the effectiveness of the
functions is significantly reduced;
⚫ (ii) result in significant damage to organizational assets;

⚫ (iii) result in significant financial loss; or

⚫ (iv) result in significant harm to individuals that does not

involve loss of life or serious, life-threatening injuries.
 High Impact
The loss could be expected to have a severe or
catastrophic adverse effect on organizational operations,
organizational assets, or individuals.
A severe or catastrophic adverse effect means that, for
example, the loss might
⚫ (i) cause a severe degradation in or loss of mission

capability to an extent and duration that the
organization is not able to perform one or more of its
primary functions;
⚫ (ii) result in major damage to organizational assets;

⚫ (iii) result in major financial loss; or

⚫ (iv) result in severe or catastrophic harm to individuals

involving loss of life or serious life threatening injuries.
 Examples of Security
Requirements
confidentiality – student grades
integrity – patient information
availability – authentication service
authenticity – admission ticket
non-repudiation – stock sell order
Computer Security Challenges
1. not simple – easy to get it wrong
2. must consider potential attacks
3. procedures used counter-intuitive
4. involve algorithms and secret info
5. must decide where to deploy mechanisms
6. battle of wits between attacker / admin
7. not perceived to be of benefit until it fails
8. requires regular monitoring
a process, not an event
1. too often an after-thought
2. regarded as impediment to using system
“Unusable security is not secure”
OSI Security Architecture
ITU-T X.800 “Security Architecture for OSI”
defines a systematic way of defining and
providing security requirements
for us it provides a useful, if abstract,
overview of concepts we will study
 OSI Security Architecture

OSI Security Architecture Explained in English with
Tables
The OSI (Open Systems Interconnection) model is a
conceptual framework used to understand network
interactions in seven layers, from the physical layer to
the application layer. Each layer has a specific role and
provides services to the layers above it. When
discussing security in the OSI model, we aim to protect
data and information across all these layers.
 OSI Security Architecture
1. Physical Layer
Security: Protecting physical devices, wires, and cables.
Example: Using surveillance cameras in data centers to prevent unauthorized
access.
2. Data Link Layer
Security: Protecting data as it travels within the local network.
Example: Using the 802.1X protocol to authenticate devices connecting to
the network.
3. Network Layer
Security: Protecting data as it moves between different networks.
Example: Using firewalls to block unauthorized access to the network.
4. Transport Layer
Security: Ensuring data integrity and correct delivery.
Example: Using TLS (Transport Layer Security) to secure data transfer
between a server and a client.
 OSI Security Architecture
5. Session Layer
Security: Managing and controlling sessions between devices.
Example: Using authentication processes to verify user identities before
starting a session.
6. Presentation Layer
Security: Encrypting and decrypting data to ensure confidentiality.
Example: Using encryption algorithms like AES (Advanced Encryption
Standard) to encrypt data before transmission.
7. Application Layer
Security: Protecting applications and services from threats.
Example: Using HTTPS protocols to secure websites.
 OSI Security Architecture
Security in OSI Model - Summary Table
 OSI Security Architecture
Practical Example: Sending an Encrypted Email
When sending an encrypted email over the internet, security measures apply
at each OSI layer:
Physical Layer: Cables used to transmit the signal.
Data Link Layer: 802.1X protocol to authenticate the sending device.
Network Layer: Firewall allowing only authorized communications.
Transport Layer: TLS securing the email transmission.
Session Layer: Managing the session between sender and receiver.
Presentation Layer: AES encryption of the email content.
Application Layer: Secure email application (e.g., Outlook) using HTTPS.
By securing data across all OSI layers, you enhance the overall security of
the network and the information exchanged on it.
OSI Security Architecture
 Aspects of Security
consider 3 aspects of information security:
⚫ security attack
⚫ security mechanism (control)
⚫ security service
note terms
⚫ threat – a potential for violation of security
⚫ vulnerability – a way by which loss can happen
⚫ attack – an assault on system security, a
deliberate attempt to evade security services
Passive Attack - Interception
Passive Attack - Interception
Passive Attack: Traffic Analysis
Active Attack: Interruption

Block delivery of message
Active Attack: Fabrication

Fabricate message
Active Attack: Replay
Active Attack: Modification

Modify message
 Handling Attacks
⚫ Passive attacks – focus on Prevention
Easy to stop
Hard to detect
⚫ Active attacks – focus on Detection and
Recovery
Hard to stop
Easy to detect
 Security Service
⚫ enhance security of data processing systems
and information transfers of an organization
⚫ intended to counter security attacks
⚫ using one or more security mechanisms
⚫ often replicates functions normally associated
with physical documents
which, for example, have signatures, dates; need
protection from disclosure, tampering, or
destruction; be notarized or witnessed; be
recorded or licensed
 Security Services
X.800:
“a service provided by a protocol layer of
communicating open systems, which ensures
adequate security of the systems or of data
transfers”

RFC 2828:
“a processing or communication service
provided by a system to give a specific kind of
protection to system resources”
 Security Services (X.800)
Authentication - assurance that communicating
entity is the one claimed
⚫ have both peer-entity & data origin authentication
Access Control - prevention of the
unauthorized use of a resource
Data Confidentiality –protection of data from
unauthorized disclosure
Data Integrity - assurance that data received is
as sent by an authorized entity
Non-Repudiation - protection against denial by
one of the parties in a communication
Availability – resource accessible/usable
 Security Mechanism
a.k.a.control
feature designed to detect, prevent, or
recover from a security attack
no single mechanism that will support all
services required
however one particular element underlies
many of the security mechanisms in use:
⚫ cryptographic techniques
hence our focus on this topic
 Security Mechanisms (X.800)
specific security mechanisms:
⚫ encipherment, digital signatures, access

controls, data integrity, authentication
exchange, traffic padding, routing control,
notarization
pervasive security mechanisms:
⚫ trusted functionality, security labels, event

detection, security audit trails, security
recovery
Model for Network Security
 Model for Network Security
using this model requires us to:
1. design a suitable algorithm for the security
transformation
2. generate the secret information (keys) used
by the algorithm
3. develop methods to distribute and share the
secret information
4. specify a protocol enabling the principals to
use the transformation and secret
information for a security service
Model for Network Access
Security
 Model for Network Access
Security
using this model requires us to:
1. select appropriate gatekeeper functions to
identify users
2. implement security controls to ensure only
authorised users access designated
information or resources
note that model does not include:
1. monitoring of system for successful
penetration
2. monitoring of authorized users for misuse
3. audit logging for forensic uses, etc.
 Summary
topicroadmap & standards organizations
security concepts:
⚫ confidentiality, integrity, availability
X.800 security architecture
security attacks, services, mechanisms
models for network (access) security