An adaptive trust based service quality monitoring mechanism for cloud computing

Cloud computing is the newest paradigm in distributed computing that delivers computing resources over the Internet as services. Due to the attractiveness of cloud computing, the market is currently flooded with many service providers. This has necessitated the customers to identify the right one meeting their requirements in terms of service quality. The existing monitoring of service quality has been limited only to quantification in cloud computing. On the other hand, the continuous improvement and distribution of service quality scores have been implemented in other distributed computing paradigms but not specifically for cloud computing. This research investigates the methods and proposes mechanisms for quantifying and ranking the service quality of service providers. The solution proposed in this thesis consists of three mechanisms, namely service quality modeling mechanism, adaptive trust computing mechanism and trust distribution mechanism for cloud computing. The Design Research Methodology (DRM) has been modified by adding phases, means and methods, and probable outcomes. This modified DRM is used throughout this study. The mechanisms were developed and tested gradually until the expected outcome has been achieved. A comprehensive set of experiments were carried out in a simulated environment to validate their effectiveness. The evaluation has been carried out by comparing their performance against the combined trust model and QoS trust model for cloud computing along with the adapted fuzzy theory based trust computing mechanism and super-agent based trust distribution mechanism, which were developed for other distributed systems. The results show that the mechanisms are faster and more stable than the existing solutions in terms of reaching the final trust scores on all three parameters tested. The results presented in this thesis are significant in terms of making cloud computing acceptable to users in verifying the performance of the service providers before making the selection

Análisis de nagios core como herramienta para el monitoreo de redes de datos

Análisis de Nagios Core como herramienta para el monitoreo de redes de datos es un trabajo que muestra de manera general los puntos relevantes sobre el monitoreo en las redes de datos: qué es el monitoreo, en dónde se aplica el monitoreo, qué métricas son relevantes para el monitoreo de las redes de datos, qué es una herramienta para el monitoreo de redes de datos, qué herramientas existen para realizar el monitoreo en las redes de datos. Estos son algunos tópicos que se discuten en el primer capítulo de esta tesina. El enfoque principal de este trabajo consiste en mostrar los puntos necesarios para poner en marcha Nagios Core en su versión 4.2.4, una herramienta de código abierto con la libertad para la personalización en varios niveles: dispositivos, servicios, alertas, resolución de problemas, entre otros; conocida por su flexibilidad y robustez al momento de monitorear ambientes de red con diversos dispositivos y servicios. El objetivo de instalar dicha herramienta es investigarla en un ambiente de red de área local e identificar las fortalezas y debilidades detectadas en la práctica

Cross-layer multi-cloud real-time application QoS monitoring and benchmarking as-a-service framework

Cloud computing provides on-demand access to affordable hardware (e.g., multi-core CPUs, GPUs, disks, and networking equipment) and software (e.g., databases, application servers and data processing frameworks) platforms with features such as elasticity, pay-per-use, low upfront investment and low time to market. This has led to the proliferation of business criti-cal applications that leverage various cloud platforms. Such applications hosted on sin-gle/multiple cloud platforms have diverse characteristics requiring extensive monitoring and benchmarking mechanisms to ensure run-time Quality of Service (QoS) (e.g., latency and throughput). The process of monitoring and benchmarking cloud applications is as yet a criti-cal issue to be further studied and addressed. Current monitoring and benchmarking approaches do not provide a holistic view of per-formance QoS for distributed applications cross cloud layers on multi-cloud environments. Furthermore, current monitoring frameworks are limited to monitoring tasks and do not in-corporate benchmarking abilities. In other words, there is no unified framework that com-bines monitoring and benchmarking functionalities. To gain the ability of both monitoring and benchmarking all under one framework will empower the cloud user to gain more in-depth control and awareness of cloud services. The Thesis identifies and discusses the major research dimensions and design issues relat-ed to developing techniques that can monitor and benchmark an application’s components cross-layers on multi-clouds. Furthermore, the thesis discusses to what extent such research dimensions and design issues are handled by current academic research papers as well as by the existing commercial monitoring tools. Moreover, the Thesis addresses an important research challenge of how to undertake cross-layer cloud monitoring and benchmarking in multi-cloud environments to provide es-sential information for effective cloud applications QoS management. It proposes, develops, implements and validates CLAMBS: Cross-Layer Multi-Cloud Application Monitoring and Benchmarking, as-a-Service Framework. The core contributions made by this thesis are the development of the CLAMBS framework and underlying monitoring and benchmarking tech-niques which are capable of: i) performing QoS monitoring of application components (e.g. ii database, web server, application server, etc.) that may be deployed across multiple cloud platforms (e.g. Amazon EC2, and Microsoft Azure); and ii) giving visibility into the QoS of in-dividual application components, which is not supported by current monitoring and bench-marking frameworks. Experiments are conducted on real-world multi-cloud platforms to em-pirically evaluate the framework and the results validate that CLAMBS can effectively monitor and benchmark applications running cross-layers on multi-clouds. The thesis presents implementation and evaluation details of the proposed CLAMBS framework. It demonstrates the feasibility and scalability of the proposed framework in real-world environments by implementing a proof-of-concept prototype on multi-cloud platforms. Finally, it presents a model for analysing the communication overheads introduced by various components (e.g. agents and manager) of CLAMBS in multi cloud environments

A software development framework for secure microservices

Abstract: The software development community has seen the proliferation of a new style of building applications based on small and specialized autonomous units of computation logic called microservices. Microservices collaborate by sending light-weight messages to automate a business task. These microservices are independently deployable with arbitrary schedules, allowing enterprises to quickly create new sets of business capabilities in response to changing business requirements. It is expected that the use of microservices will become the default style of building software applications by the year 2023, with the microservices’ market projected to reach thirtytwo billion United States of American dollars. The adoption of microservices presents new security challenges due to the way the units of computation logic are designed, deployed and maintained. The decomposition of an application into small independent units increases the attack surface, and makes it a challenge to secure and control network traffic for each unit. These new security challenges cannot be addressed by traditional security strategies. Software engineers developing microservices are facing growing pressure to build secure microservices to ensure the security of business information assets and guarantee business continuity. The research conducted in this thesis proposes a software development framework that software engineers can use to build secure microservices. The framework defines artefacts, development and maintenance activities together with methods and techniques that software engineers can use to ensure that microservices are developed from the ground up to be secure. The goal of the framework is to ensure that microservices are designed and built to be able to detect, react, respond and recover from attacks during day-to-day operations. To prove the capability of the framework, a microservices-based application is developed using the proposed software development framework as part of an experiment to determine its effectiveness. These results, together with a comparative and quality review of the framework indicate that the software development framework can be effectively used to develop secure microservices.Ph.D. (Computer Science