A Novel IP Traceback Scheme for Spoofing Attack

Internet has been widely applied in various fields, more and more network security issues emerge and catch people\u27s attention. However, adversaries often hide themselves by spoofing their own IP addresses and then launch attacks. For this reason, researchers have proposed a lot of trace back schemes to trace the source of these attacks. Some use only one packet in their packet logging schemes to achieve IP tracking. Others combine packet marking with packet logging and therefore create hybrid IP trace back schemes demanding less storage but requiring a longer search. In this paper, we propose a new hybrid IP trace back scheme with efficient packet logging aiming to have a fixed storage requirement for each router in packet logging without the need to refresh the logged tracking information and to achieve zero false positive and false negative rates in attack-path reconstruction

Avoiditals: Enhanced Cyber-Attack Taxonomy In Securing Information Technology Infrastructure

An operation of an organization is currently using a digital environment which opens to potential cyber-attacks. These phenomena become worst as the cyberattack landscape is changing rapidly. The impact of cyber-attacks varies depending on the scope of the organization and the value of assets that need to be protected. It is difficult to assess the damage to an organization from cyberattacks due to a lack of understanding of tools, metrics, and knowledge on the type of attacks and their impacts. Hence, this paper aims to identify domains and sub-domains of cyber-attack taxonomy to facilitate the understanding of cyber-attacks. Four phases are carried in this research: identify existing cyber-attack taxonomy, determine and classify domains and sub-domains of cyber-attack, and construct the enhanced cyber-attack taxonomy. The existing cyber-attack taxonomies are analyzed, domains and sub-domains are selected based on the focus and objectives of the research, and the proposed taxonomy named AVOIDITALS Cyber-attack Taxonomy is constructed. AVOIDITALS consists of 8 domains, 105 sub-domains, 142 sub-sub-domains, and 90 other sub-sub-domains that act as a guideline to assist administrators in determining cyber-attacks through cyber-attacks pattern identification that commonly occurred on digital infrastructure and provide the best prevention method to minimize impact. This research can be further developed in line with the emergence of new types and categories of current cyberattacks and the future

Defence against Denial of Service (DoS) attacks using Identifier-Locator Network Protocol (ILNP) and Domain Name System (DNS)

This research considered a novel approach to network security by combining a new networking architecture based on the Identifier-Locator Network Protocol (ILNP) and the existing Domain Name System (DNS). Specifically, the investigations considered the mitigation of network-level and transport-level based Denial of Service (DoS) attacks. The solutions presented for DoS are applicable to secure servers that are visible externally from an enterprise network. DoS was chosen as an area of concern because in recent years DoS has become the most common and hard to defend against attacks. The novelty of this approach was to consider the way the DNS and ILNP can work together, transparently to the application, within an enterprise scenario. This was achieved by the introduction of a new application-level access control function - the Capability Management System (CMS) - which applies configuration at the application level (DNS data) and network level (ILNP namespaces). CMS provides dynamic, ephemeral identity and location information to clients and servers, in order to effectively partition legitimate traffic from attack traffic. This was achieved without modifying existing network components such as switches and routers and making standard use of existing functions, such as access control lists, and DNS servers, all within a single trust domain that is under the control of the enterprise. The prime objectives of this research were: • to defend against DoS attacks with the use of naming and DNS within an enterprise scenario. • to increase the attacker’s effort in launching a successful DoS attack. • to reduce the visibility of vulnerabilities that can be discovered by an attacker by active probing approaches. • to practically demonstrate the effectiveness of ILNP and DNS working together to provide a solution for DoS mitigation. The solution methodology is based on the use of network and transport level capabilities, dynamic changes to DNS data, and a Moving Target Defence (MTD) paradigm. There are three solutions presented which use ILNP namespaces. These solutions are referred to as identifier-based, locator-based, and combined identifier-locator based solutions, respectively. ILNP-based node identity values were used to provide transport-level per-client server capabilities, thereby providing per-client isolation of traffic. ILNP locator values were used to allow a provision of network-level traffic separation for externally accessible enterprise services. Then, the identifier and locator solutions were combined, showing the possibility of protecting the services, with per-client traffic control and topological traffic path separation. All solutions were site-based solutions and did not require any modification in the core/external network, or the active cooperation of an ISP, therefore limiting the trust domain to the enterprise itself. Experiments were conducted to evaluate all the solutions on a test-bed consisting of off-the-shelf hardware, open-source software, an implementation of the CMS written in C, all running on Linux. The discussion includes considering the efficacy of the solutions, comparisons with existing methods, the performance of each solution, and critical analysis highlighting future improvements that could be made