Pioneering a Prototype VPN-Based Cloud Strategy For Streamlined Library Management

This article showcases a prototype VPN-based cloud strategy that uses SoftEther VPN and Microsoft Azure to manage and exchange library management systems and repositories. The prototype was tested for performance, security, and scalability, and the results suggest that the VPN-based cloud strategy is a viable solution for managing distributed library repositories. By using SoftEther VPN and Microsoft Azure, the prototype provided secure communication and scalability to handle large numbers of concurrent users. Future research can explore other VPN technologies and cloud platforms to enhance the prototype\u27s capabilities and evaluate its performance in various scenarios

A Survey of VPN Performance Evaluation

Virtual Private Network (VPN) is commonly used in business situations to provide secure communication channels over public infrastructure such as Internet. A VPN operates by passing data over the Internet or corporate intranet through ?tunnels? which are secure, encrypted virtual connections that use the Internet as the connection medium[13].The VPN establishes tunnels between servers in a site-to-site VPN, clients and servers in a client-to site VPN[13]. VPN is a technology that does provide security strong enough for business use. However, performance of these networks is also important in that lowering network and server resources can lower costs and improve user satisfaction.VPN have many protocols PPTP, L2TP, IPSec for the performance and security. In this research we evaluate performance of VPN using IPSec (Internet Protocol Security). IPSec is a framework for a set of protocols and algorithms for security at the network layer by authenticating and encrypting each packet between two IPSec gateways (GWs).So IPSec protocol is better than the other protocol it give better performance than the other protocol

Implementation and Provisioning of Federated Networks in Hybrid Clouds (pre-print)

Federated cloud networking is needed to allow the seamless and efficient interconnection of resources distributed among different clouds. This work introduces a new cloud network federation framework for the automatic provision of Layer 2 (L2) and layer 3 (L3) virtual networks to interconnect geographically distributed cloud infrastructures in a hybrid cloud scenario. After a revision of existing encapsulation technologies to implement L2 and L3 overlay networks, the paper analyzes the main topologies that can be used to construct federated network overlays within hybrid clouds. In order to demonstrate the proposed solution and compare the different topologies, the article shows a proof-of-concept of a real federated network deployment in a hybrid cloud, which spans a local private cloud, managed with OpenNebula, and two public clouds, two different regions of mazon EC2. Results show that L2 and L3 overlay connectivity can be achieved with a minimal bandwidth overhead, lower than 10%

Pando: Personal Volunteer Computing in Browsers

The large penetration and continued growth in ownership of personal electronic devices represents a freely available and largely untapped source of computing power. To leverage those, we present Pando, a new volunteer computing tool based on a declarative concurrent programming model and implemented using JavaScript, WebRTC, and WebSockets. This tool enables a dynamically varying number of failure-prone personal devices contributed by volunteers to parallelize the application of a function on a stream of values, by using the devices' browsers. We show that Pando can provide throughput improvements compared to a single personal device, on a variety of compute-bound applications including animation rendering and image processing. We also show the flexibility of our approach by deploying Pando on personal devices connected over a local network, on Grid5000, a French-wide computing grid in a virtual private network, and seven PlanetLab nodes distributed in a wide area network over Europe.Comment: 14 pages, 12 figures, 2 table

Development of a Web Based Monitoring System for a Distributed and Modern Production

AbstractWeb technologies have experienced a rapid development in recent years. In particular web browsers enhanced their abilities because of the improvement of JavaScript, CSS3 and HTML5. Hence, richer web-based software solutions with an increasing range of functions are available. By using responsive web design (RWD), a technology to display content without resizing on different screens, developers are able to support a diverse range of devices with small effort.In order to enable a monitoring of the current status of a production system, signals of many different sensors, machine and production data are required. Combining microcontrollers with sensors to embedded sensors enables an efficient way to communicate with web services. Due to the strong decline of prices for semiconductor technologies, companies are able to set up production machines with these technologies at low costs.This paper presents a way to set up a distributed manufacturing control system by using common web technologies like RWD and embedded systems. We discuss advantages and drawbacks of web-based software solutions and show a methodical approach for the use in a modern production system. Finally, the functionality of the method is proven within an application example