Intrusion detection systems (IDS) have been widely adopted within the IT community, as
passive monitoring tools that report security related problems to system administrators.
However, the increasing number and evolving complexity of attacks, along with the
growth and complexity of networking infrastructures, has led to overwhelming numbers of
IDS alerts, which allow significantly smaller timeframe for a human to respond. The need
for automated response is therefore very much evident. However, the adoption of such
approaches has been constrained by practical limitations and administrators' consequent
mistrust of systems' abilities to issue appropriate responses.
The thesis presents a thorough analysis of the problem of intrusions, and identifies false
alarms as the main obstacle to the adoption of automated response. A critical examination
of existing automated response systems is provided, along with a discussion of why a new
solution is needed. The thesis determines that, while the detection capabilities remain
imperfect, the problem of false alarms cannot be eliminated. Automated response
technology must take this into account, and instead focus upon avoiding the disruption of
legitimate users and services in such scenarios. The overall aim of the research has
therefore been to enhance the automated response process, by considering the context of an
attack, and investigate and evaluate a means of making intelligent response decisions.
The realisation of this objective has included the formulation of a response-oriented
taxonomy of intrusions, which is used as a basis to systematically study intrusions and
understand the threats detected by an IDS. From this foundation, a novel Flexible
Automated and Intelligent Responder (FAIR) architecture has been designed, as the basis
from which flexible and escalating levels of response are offered, according to the context
of an attack. The thesis describes the design and operation of the architecture, focusing
upon the contextual factors influencing the response process, and the way they are
measured and assessed to formulate response decisions. The architecture is underpinned by
the use of response policies which provide a means to reflect the changing needs and
characteristics of organisations.
The main concepts of the new architecture were validated via a proof-of-concept prototype
system. A series of test scenarios were used to demonstrate how the context of an attack
can influence the response decisions, and how the response policies can be customised and
used to enable intelligent decisions. This helped to prove that the concept of flexible
automated response is indeed viable, and that the research has provided a suitable
contribution to knowledge in this important domain.
Date of Award | 2004 |
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Original language | English |
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Awarding Institution | |
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CLASSIFYING AND RESPONDING TO NETWORK INTRUSIONS
PAPADAKI, M. (Author). 2004
Student thesis: PhD