Biblio

Edge computing requires a flexible choice of data-processing and rapidly computation performed at the edge of networks. We proposed an edge computing platform with container-based virtualization technology. In the platform, data-processing instances are modularized and deployed to edge nodes suitable for user requirements with keeping the data-processing flows within wide area network. This paper reports the platform controller and the process modules implemented to realize the secure and flexible edge computing platform.

Larger companies need more sites in the wide area network (WAN). However, internet service providers cannot obtain sufficient capacity to handle peak traffic, causing a terrible delay. The software-defined network (SDN) allows to own more programmability, adaptability, and application-aware, but scalability is a critical problem for merging both. This paper proposes a solution based on Protocol-Oblivious Forwarding (POF). It is a higher degree of decoupling control and data planes. The control plane uses fields unrelated to the protocol to unify packet match and route, and the data plane uses a set of general flow instructions in fast forwarding. As a result, we only save three flow tables on the forwarding paths so that each packet keeps a pipeline in the source route header to mark the next output ports. This solution can support a constant delay while the network expands.

With software defined networking and network function virtualization technologies, networks can be programmed to have customized processing and paths for different traffic at manageable costs and for massive numbers of applications. Now, picture a future Internet where each entity - a person, an organization, or an autonomous system - has the ability to choose how traffic in their respective network sessions is routed and processed between itself and its counterparts. The network is, essentially, liberated from today's homogeneous IP-based routing and limited connection options. To realize such a network paradigm, we propose a software defined exchange architecture that can provide the needed network programmability, session-level customization, and scale. We present a case study for traffic-analysis-resistant communication among individuals, campuses, or web services, where IP addresses no longer need to have a one-to-one correspondence with service providers.