8 research outputs found
Multilevel security within the Army Tactical Command Control System: an implementation strategy
As U.S. Forces continue to operate in coalition environments, the need to incorporate Multilevel Security into the ATCCS becomes more apparent. While Army doctrine requires the ATCCS to be MLS to the B2 level, there iii currently no product or technology developed to fulfill this requirement, nor is there any implementation strategy devised to address this issue. This thesis proposes two strategies to implement MLS within the ATCCS: a target and near term implementation strategy. These two strategies are derived from the DoD joint MLS Technology Insertion Program Target Architecture and Implementation Strategy, which provides the vehicle for assessing the current and in development MLS products and capabilitieshttp://archive.org/details/multilevelsecuri00lopeCaptain, United States ArmyApproved for public release; distribution is unlimited
Performance study of a COTS Distributed DBMS adapted for multilevel security
Multilevel secure database management system (MLS/DBMS) products
no longer enjoy direct commercial-off-the-shelf (COTS) support.
Meanwhile, existing users of these MLS/DBMS products continue to
rely on them to satisfy their multilevel security requirements.
This calls for a new approach to developing MLS/DBMS systems, one
that relies on adapting the features of existing COTS database
products rather than depending on the traditional custom design
products to provide continuing MLS support.
We advocate fragmentation as a good basis for implementing
multilevel security in the new approach because it is well
supported in some current COTS database management systems. We
implemented a prototype that utilises the inherent advantages of
the distribution scheme in distributed databases for controlling
access to single-level fragments; this is achieved by augmenting
the distribution module of the host distributed DBMS with MLS code
such that the clearance of the user making a request is always
compared to the classification of the node containing the
fragments referenced; requests to unauthorised nodes are simply
dropped.
The prototype we implemented was used to instrument a series of
experiments to determine the relative performance of the tuple,
attribute, and element level fragmentation schemes. Our
experiments measured the impact on the front-end and the network
when various properties of each scheme, such as the number of
tuples, attributes, security levels, and the page size, were
varied for a Selection and Join query. We were particularly
interested in the relationship between performance degradation and
changes in the quantity of these properties. The performance of
each scheme was measured in terms of its response time.
The response times for the element level fragmentation scheme
increased as the numbers of tuples, attributes, security levels,
and the page size were increased, more significantly so than when
the number of tuples and attributes were increased. The response
times for the attribute level fragmentation scheme was the
fastest, suggesting that the performance of the attribute level
scheme is superior to the tuple and element level fragmentation
schemes. In the context of assurance, this research has also shown
that the distribution of fragments based on security level is a
more natural approach to implementing security in MLS/DBMS
systems, because a multilevel database is analogous to a
distributed database based on security level.
Overall, our study finds that the attribute level fragmentation
scheme demonstrates better performance than the tuple and element
level schemes. The response times (and hence the performance) of
the element level fragmentation scheme exhibited the worst
performance degradation compared to the tuple and attribute level
schemes
Reflections on the 30th Anniversary of the IEEE Symposium on Security and Privacy
Peter G. Neumann, Matt Bishop, Sean Peisert, and Marv Schaefer, "Reflections on the 30th Anniversary of the IEEE Symposium on Security and Privacy," Proceedings of the 31st IEEE Symposium on Security and Privacy, pp. 3–13, Oakland/Berkeley, CA, May 16–19, 2010
Security-Driven Software Evolution Using A Model Driven Approach
High security level must be guaranteed in applications in order to mitigate risks during the deployment of information systems in open network environments. However, a significant number of legacy systems remain in use which poses security risks to the enterprise’ assets due to the poor technologies used and lack of security concerns when they were in design. Software reengineering is a way out to improve their security levels in a systematic way. Model driven is an approach in which model as defined by its type directs the execution of the process. The aim of this research is to explore how model driven approach can facilitate the software reengineering driven by security demand. The research in this thesis involves the following three phases.
Firstly, legacy system understanding is performed using reverse engineering techniques. Task of this phase is to reverse engineer legacy system into UML models, partition the legacy system into subsystems with the help of model slicing technique and detect existing security mechanisms to determine whether or not the provided security in the legacy system satisfies the user’s security objectives.
Secondly, security requirements are elicited using risk analysis method. It is the process of analysing key aspects of the legacy systems in terms of security. A new risk assessment method, taking consideration of asset, threat and vulnerability, is proposed and used to elicit the security requirements which will generate the detailed security requirements in the specific format to direct the subsequent security enhancement.
Finally, security enhancement for the system is performed using the proposed ontology based security pattern approach. It is the stage that security patterns derived from security expertise and fulfilling the elicited security requirements are selected and integrated in the legacy system models with the help of the proposed security ontology.
The proposed approach is evaluated by the selected case study. Based on the analysis, conclusions are drawn and future research is discussed at the end of this thesis. The results show this thesis contributes an effective, reusable and suitable evolution approach for software security
Secure Compartmented Data Access over an Untrusted Network Using a COTS-based Architecture
In this paper, we present an approach to secure compartmented data access over an untrusted network using a secure network computing architecture. We describe the architecture and show how application-level firewalls and other commercial-off-the-shelf (COTS) products may be used to implement compartmentalized access to sensitive information and to provide access control over an untrusted network and in a variety of environments. Security-related issues and assumptions are discussed. We compare our architecture to other models of controlling access to sensitive data and draw conclusions about the requirements for high-security solutions for electronic business as well as DoD applications. 1
PROACTIVE BIOMETRIC-ENABLED FORENSIC IMPRINTING SYSTEM
Insider threats are a significant security issue. The last decade has witnessed countless instances of data loss and exposure in which leaked data have become publicly available and easily accessible. Losing or disclosing sensitive data or confidential information may cause substantial financial and reputational damage to a company. Therefore, preventing or responding to such incidents has become a challenging task. Whilst more recent research has focused explicitly on the problem of insider misuse, it has tended to concentrate on the information itself—either through its protection or approaches to detecting leakage. Although digital forensics has become a de facto standard in the investigation of criminal activities, a fundamental problem is not being able to associate a specific person with particular electronic evidence, especially when stolen credentials and the Trojan defence are two commonly cited arguments. Thus, it is apparent that there is an urgent requirement to develop a more innovative and robust technique that can more inextricably link the use of information (e.g., images and documents) to the users who access and use them. Therefore, this research project investigates the role that transparent and multimodal biometrics could play in providing this link by leveraging individuals’ biometric information for the attribution of insider misuse identification. This thesis examines the existing literature in the domain of data loss prevention, detection, and proactive digital forensics, which includes traceability techniques. The aim is to develop the current state of the art, having identified a gap in the literature, which this research has attempted to investigate and provide a possible solution. Although most of the existing methods and tools used by investigators to conduct examinations of digital crime help significantly in collecting, analysing and presenting digital evidence, essential to this process is that investigators establish a link between the notable/stolen digital object and the identity of the individual who used it; as opposed to merely using an electronic record or a log that indicates that the user interacted with the object in question (evidence). Therefore, the proposed approach in this study seeks to provide a novel technique that enables capturing individual’s biometric identifiers/signals (e.g. face or keystroke dynamics) and embedding them into the digital objects users are interacting with. This is achieved by developing two modes—a centralised or decentralised manner. The centralised approach stores the mapped information alongside digital object identifiers in a centralised storage repository; the decentralised approach seeks to overcome the need for centralised storage by embedding all the necessary information within the digital object itself. Moreover, no explicit biometric information is stored, as only the correlation that points to those locations within the imprinted object is preserved. Comprehensive experiments conducted to assess the proposed approach show that it is highly possible to establish this correlation even when the original version of the examined object has undergone significant modification. In many scenarios, such as changing or removing part of an image or document, including words and sentences, it was possible to extract and reconstruct the correlated biometric information from a modified object with a high success rate. A reconstruction of the feature vector from unmodified images was possible using the generated imprints with 100% accuracy. This was achieved easily by reversing the imprinting processes. Under a modification attack, in which the imprinted object is manipulated, at least one imprinted feature vector was successfully retrieved from an average of 97 out of 100 images, even when the modification percentage was as high as 80%. For the decentralised approach, the initial experimental results showed that it was possible to retrieve the embedded biometric signals successfully, even when the file (i.e., image) had had 75% of its original status modified. The research has proposed and validated a number of approaches to the embedding of biometric data within digital objects to enable successful user attribution of information leakage attacks.Embassy of Saudi Arabia in Londo
Summary of Research 1994
The views expressed in this report are those of the authors and do not reflect the
official policy or position of the Department of Defense or the U.S. Government.This report contains 359 summaries of research projects which were carried out
under funding of the Naval Postgraduate School Research Program. A list of recent
publications is also included which consists of conference presentations and
publications, books, contributions to books, published journal papers, and
technical reports. The research was conducted in the areas of Aeronautics and
Astronautics, Computer Science, Electrical and Computer Engineering, Mathematics,
Mechanical Engineering, Meteorology, National Security Affairs, Oceanography,
Operations Research, Physics, and Systems Management. This also includes research
by the Command, Control and Communications (C3) Academic Group, Electronic Warfare
Academic Group, Space Systems Academic Group, and the Undersea Warfare Academic
Group