2,280 research outputs found
Towards a Trustworthy Thin Terminal for Securing Enterprise Networks
Organizations have many employees that lack the technical knowledge to securely operate their machines. These users may open malicious email attachments/links or install unverified software such as P2P programs. These actions introduce significant risk to an organization\u27s network since they allow attackers to exploit the trust and access given to a client machine. However, system administrators currently lack the control of client machines needed to prevent these security risks. A possible solution to address this issue lies in attestation. With respect to computer science, attestation is the ability of a machine to prove its current state. This capability can be used by client machines to remotely attest to their state, which can be used by other machines in the network when making trust decisions. Previous research in this area has focused on the use of a static root of trust (RoT), requiring the use of a chain of trust over the entire software stack. We would argue this approach is limited in feasibility, because it requires an understanding and evaluation of the all the previous states of a machine. With the use of late launch, a dynamic root of trust introduced in the Trusted Platform Module (TPM) v1.2 specification, the required chain of trust is drastically shortened, minimizing the previous states of a machine that must be evaluated. This reduced chain of trust may allow a dynamic RoT to address the limitations of a static RoT. We are implementing a client terminal service that utilizes late launch to attest to its execution. Further, the minimal functional requirements of the service facilitate strong software verification. The goal in designing this service is not to increase the security of the network, but rather to push the functionality, and therefore the security risks and responsibilities, of client machines to the network€™s servers. In doing so, we create a platform that can more easily be administered by those individuals best equipped to do so with the expectation that this will lead to better security practices. Through the use of late launch and remote attestation in our terminal service, the system administrators have a strong guarantee the clients connecting to their system are secure and can therefore focus their efforts on securing the server architecture. This effectively addresses our motivating problem as it forces user actions to occur under the control of system administrators
Trusted Computing and Secure Virtualization in Cloud Computing
Large-scale deployment and use of cloud computing in industry
is accompanied and in the same time hampered by concerns regarding protection of
data handled by cloud computing providers. One of the consequences of moving
data processing and storage off company premises is that organizations have
less control over their infrastructure. As a result, cloud service (CS) clients
must trust that the CS provider is able to protect their data and
infrastructure from both external and internal attacks. Currently however, such
trust can only rely on organizational processes declared by the CS
provider and can not be remotely verified and validated by an external party.
Enabling the CS client to verify the integrity of the host where the
virtual machine instance will run, as well as to ensure that the virtual
machine image has not been tampered with, are some steps towards building
trust in the CS provider. Having the tools to perform such
verifications prior to the launch of the VM instance allows the CS
clients to decide in runtime whether certain data should be stored- or calculations
should be made on the VM instance offered by the CS provider.
This thesis combines three components -- trusted computing, virtualization technology
and cloud computing platforms -- to address issues of trust and
security in public cloud computing environments. Of the three components,
virtualization technology has had the longest evolution and is a cornerstone
for the realization of cloud computing. Trusted computing is a recent
industry initiative that aims to implement the root of trust in a hardware
component, the trusted platform module. The initiative has been formalized
in a set of specifications and is currently at version 1.2. Cloud computing
platforms pool virtualized computing, storage and network resources in
order to serve a large number of customers customers that use a multi-tenant
multiplexing model to offer on-demand self-service over broad network.
Open source cloud computing platforms are, similar to trusted computing, a
fairly recent technology in active development.
The issue of trust in public cloud environments is addressed
by examining the state of the art within cloud computing security and
subsequently addressing the issues of establishing trust in the launch of a
generic virtual machine in a public cloud environment. As a result, the thesis
proposes a trusted launch protocol that allows CS clients
to verify and ensure the integrity of the VM instance at launch time, as
well as the integrity of the host where the VM instance is launched. The protocol
relies on the use of Trusted Platform Module (TPM) for key generation and data protection.
The TPM also plays an essential part in the integrity attestation of the
VM instance host. Along with a theoretical, platform-agnostic protocol,
the thesis also describes a detailed implementation design of the protocol
using the OpenStack cloud computing platform.
In order the verify the implementability of the proposed protocol, a prototype
implementation has built using a distributed deployment of OpenStack.
While the protocol covers only the trusted launch procedure using generic
virtual machine images, it presents a step aimed to contribute towards
the creation of a secure and trusted public cloud computing environment
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