Biblio

In Named Data Networking (NDN) architectures, a content object is located according to the content's identifier and can be retrieved from all nodes that hold a replica of the content. The default forwarding strategy of NDN is to forward an Interest packet along the default path from the requester to the server to find a content object according to its name prefix. However, the best path may not be the default path, since content might also be located nearby. Hence, the default strategy could result in a sub-optimal delivery efficiency. To address this issue we introduce a vicinity-based replica finding scheme. This is based on the observation that content objects might be requested several times. Therefore, replicas can be often cached within a particular neighbourhood and thus it might be efficient to specifically look for them in order to improve the content delivery performance. Within this paper, we evaluate the optimal size of the vicinity within which content should be located (i.e. the distance between the requester and its neighbours that are considered within the content search). We also compare the proposed scheme with the default NDN forwarding strategy with respect to replica finding efficiency and network overhead. Using the proposed scheme, we demonstrate that the replica finding mechanism reduces the delivery time effectively with acceptable overhead costs.

Efficient authentication, authorization, and accounting (AAA) management mechanisms will be key for the widespread adoption of SDN experimentation facilities beyond the confines of academic labs. In particular, we are interested in a robust AAA infrastructure to identify experimenters, police their actions based on the associated roles, facilitate secure resource sharing, and provide for detailed accountability. Currently, however, said facilities are forced to employ a patchy AAA infrastructure which lacks several of the aforementioned features. This paper proposes a certificate-based AAA architecture for SDN experimental facilities, which is by design both secure and flexible. As this work is implementation-driven and aims for a short deployment cycle in current facilities, we also outline a credible migration path which we are currently pursuing actively.