640 research outputs found
Trusted Energy-Efficient Cloud-based Services Brokerage Platform
The use of cloud computing can increase service efficiency and service level agreements for cloud users, by linking them to an appropriate cloud service provider, using the cloud services brokerage paradigm. Cloud service brokerage represents a promising new layer which is to be added to the cloud computing network, which manages the use, performance and delivery of cloud services, and negotiates relationships between cloud service providers and cloud service consumers. The work presented in this paper studies the research related to cloud service brokerage systems along with the weaknesses and vulnerabilities associated with each of these systems, with a particular focus on the multicloud-based services environment. In addition, the paper will conclude with a proposed multi-cloud framework that overcomes the weaknesses of other listed cloud brokers. The new framework aims to find the appropriate data centre in terms of energy efficiency, QoS and SLA. Moreover, it presents a security model aims to protect the proposed multicloud framework and highlights the key features that must be available in multi-cloud-based brokerage systems
Towards trustworthy end-to-end communication in industry 4.0
Industry 4.0 considers integration of IT and control systems with physical objects, software, sensors and connectivity in order to optimize manufacturing processes. It provides advanced functionalities in control and communication for an infrastructure that handles multiple tasks in various locations automatically. Automatic actions require information from trustworthy sources. Thus, this work is focused on how to ensure trustworthy communication from the edge devices to the backend infrastructure. We derive a meta-model based on RAMI 4.0, which is used to describe an end-to-end communication use case for an Industry 4.0 application scenario and to identify dependabilities in case of security challenges. Furthermore, we evaluate secure messaging protocols and the integration of Trusted Platform Module (TPM) as a root of trust for dataexchange. We define a set of representative measurable indicator points based on existing standards and use them for automated dependability detection within the whole system
A Framework for Securing Health Information Using Blockchain in Cloud Hosted Cyber Physical Systems
Electronic Health Records (EHRs) have undergone numerous technical
improvements in recent years, including the incorporation of mobile devices
with the cloud computing technologies to facilitate medical data exchanges
between patients and the healthcare professionals. This cutting-edge
architecture enables cyber physical systems housed in the cloud to provide
healthcare services with minimal operational costs, high flexibility, security,
and EHR accessibility. If patient health information is stored in the hospital
database, there will always be a risk of intrusion, i.e., unauthorized file
access and information modification by attackers. To address this concern, we
propose a decentralized EHR system based on Blockchain technology. To
facilitate secure EHR exchange across various patients and medical providers,
we develop a reliable access control method based on smart contracts. We
incorporate Cryptocurrency, specifically Ethereum, in the suggested system to
protect sensitive health information from potential attackers. In our suggested
approach, both physicians and patients are required to be authenticated.
Patients can register, and a block with a unique hash value will be generated.
Once the patient discusses the disease with the physician, the physician can
check the patient's condition and offer drugs. For experimental findings, we
employ the public Block chain Ganache and solidity remix-based smart contracts
to protect privacy. Ethers are used as the crypto currencies
A reactive architecture for cloud-based system engineering
PhD ThesisSoftware system engineering is increasingly practised over globally distributed locations. Such a practise is termed as Global Software Development (GSD). GSD has become a business necessity mainly because of the
scarcity of resources, cost, and the need to locate development closer to
the customers. GSD is highly dependent on requirements management,
but system requirements continuously change. Poorly managed change in
requirements affects the overall cost, schedule and quality of GSD projects.
It is particularly challenging to manage and trace such changes, and hence
we require a rigorous requirement change management (RCM) process.
RCM is not trivial in collocated software development; and with the presence of geographical, cultural, social and temporal factors, it makes RCM
profoundly difficult for GSD. Existing RCM methods do not take into
consideration these issues faced in GSD. Considering the state-of-the-art
in RCM, design and analysis of architecture, and cloud accountability,
this work contributes:
1. an alternative and novel mechanism for effective information and
knowledge-sharing towards RCM and traceability.
2. a novel methodology for the design and analysis of small-to-medium
size cloud-based systems, with a particular focus on the trade-off of
quality attributes.
3. a dependable framework that facilitates the RCM and traceability
method for cloud-based system engineering.
4. a novel methodology for assuring cloud accountability in terms of
dependability.
5. a cloud-based framework to facilitate the cloud accountability methodology.
The results show a traceable RCM linkage between system engineering
processes and stakeholder requirements for cloud-based GSD projects,
which is better than existing approaches. Also, the results show an improved dependability assurance of systems interfacing with the unpredictable cloud environment. We reach the conclusion that RCM with
a clear focus on traceability, which is then facilitated by a dependable
framework, improves the chance of developing a cloud-based GSD project
successfully
Unified representation of monitoring information across federated cloud infrastructures
Nowadays one of the issues hindering the potential of federating cloud-based infrastructures to reach much larger scales is their standard management and monitoring. In particular, this is true in cases where these federated infrastructures provide emerging Future Internet and Smart Cities-oriented services, such as the Internet of Things (IoT), that benefit from cloud services. The contribution of this paper is the introduction of a unified monitoring architecture for federated cloud infrastructures accompanied by the adoption of a uniform representation of measurement data. The presented solution is capable of providing multi-domain compatibility, scalability, as well as the ability to analyze large amounts of monitoring data, collected from datacenters and offered through open and standardized APIs. The solution described herein has been deployed and is currently running on a community of 5 infrastructures within the framework of the European Project XIFI, to be extended to 12 more infrastructures
A trust label system for communicating trust in cloud services.
Cloud computing is rapidly changing the digital service landscape. A proliferation of Cloud providers has emerged, increasing the difficulty of consumer decisions. Trust issues have been identified as a factor holding back Cloud adoption. The risks and challenges inherent in the adoption of Cloud services are well recognised in the computing literature. In conjunction with these risks, the relative novelty of the online environment as a context for the provision of business services can increase consumer perceptions of uncertainty. This uncertainty is worsened in a Cloud context due to the lack of transparency, from the consumer perspective, into the service types, operational conditions and the quality of service offered by the diverse providers. Previous approaches failed to provide an appropriate medium for communicating trust and trustworthiness in Clouds. A new strategy is required to improve consumer confidence and trust in Cloud providers. This paper presents the operationalisation of a trust label system designed to communicate trust and trustworthiness in Cloud services. We describe the technical details and implementation of the trust label components. Based on a use case scenario, an initial evaluation was carried out to test its operations and its usefulness for increasing consumer trust in Cloud services.N/
A Cloud-Based Collaboration Platform for Model-Based Design of Cyber-Physical Systems
Businesses, particularly small and medium-sized enterprises, aiming to start
up in Model-Based Design (MBD) face difficult choices from a wide range of
methods, notations and tools before making the significant investments in
planning, procurement and training necessary to deploy new approaches
successfully. In the development of Cyber-Physical Systems (CPSs) this is
exacerbated by the diversity of formalisms covering computation, physical and
human processes. In this paper, we propose the use of a cloud-enabled and open
collaboration platform that allows businesses to offer models, tools and other
assets, and permits others to access these on a pay-per-use basis as a means of
lowering barriers to the adoption of MBD technology, and to promote
experimentation in a sandbox environment
Service Quality and Profit Control in Utility Computing Service Life Cycles
Utility Computing is one of the most discussed business models in the context of Cloud Computing. Service providers are more and more pushed into the role of utilities by their customer's expectations. Subsequently, the demand for predictable service availability and pay-per-use pricing models increases. Furthermore, for providers, a new opportunity to optimise resource usage offers arises, resulting from new virtualisation techniques. In this context, the control of service quality and profit depends on a deep understanding of the representation of the relationship between business and technique.
This research analyses the relationship between the business model of Utility Computing and Service-oriented Computing architectures hosted in Cloud environments. The relations are clarified in detail for the entire service life cycle and throughout all architectural layers. Based on the elaborated relations, an approach to a delivery framework is evolved, in order to enable the optimisation of the relation attributes, while the service implementation passes through business planning, development, and operations.
Related work from academic literature does not cover the collected requirements on service offers in this context. This finding is revealed by a critical review of approaches in the fields of Cloud Computing, Grid Computing, and Application Clusters. The related work is analysed regarding appropriate provision architectures and quality assurance approaches.
The main concepts of the delivery framework are evaluated based on a simulation model. To demonstrate the ability of the framework to model complex pay-per-use service cascades in Cloud environments, several experiments have been conducted. First outcomes proof that the contributions of this research undoubtedly enable the optimisation of service quality and profit in Cloud-based Service-oriented Computing architectures
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