The HSS/SNiC : a conceptual framework for collapsing security down to the physical layer

This work details the concept of a novel network security model called the Super NIC (SNIC) and a Hybrid Super Switch (HSS). The design will ultimately incorporate deep packet inspection (DPI), intrusion detection and prevention (IDS/IPS) functions, as well as network access control technologies therefore making all end-point network devices inherently secure. The SNIC and HSS functions are modelled using a transparent GNU/Linux Bridge with the Netfilter framework

Optically reconfigurable 1 x 4 remote node switch for access networks

In this paper we demonstrate an optically controlled 1 x 4 remote node switch, based on membrane InP switches bonded to a silicon-on-insulator circuit. We show that the switch exhibits cross talk better than 25 dB between the output ports, and that the switch operates without receiver sensitivity penalty. Furthermore, the proposed switch architecture allows for optical clock distribution as a means to avoid the need for clock recovery at the receiver side. This is demonstrated in a proof-of-principle experiment where data and clock are sent through a single membrane InP switch

Quantifying the latency benefits of near-edge and in-network FPGA acceleration

Transmitting data to cloud datacenters in distributed IoT applications introduces significant communication latency, but is often the only feasible solution when source nodes are computationally limited. To address latency concerns, cloudlets, in-network computing, and more capable edge nodes are all being explored as a way of moving processing capability towards the edge of the network. Hardware acceleration using Field Programmable Gate Arrays (FPGAs) is also seeing increased interest due to reduced computation latency and improved efficiency. This paper evaluates the the implications of these offloading approaches using a case study neural network based image classification application, quantifying both the computation and communication latency resulting from different platform choices. We consider communication latency including the ingestion of packets for processing on the target platform, showing that this varies significantly with the choice of platform. We demonstrate that emerging in-network accelerator approaches offer much improved and predictable performance as well as better scaling to support multiple data sources

Reconfigurable framework for high-bandwidth stream-oriented data processing

Designing a digital system that implements an assortment of specialized high performance algorithms can be costly. Considerable non-recurring engineering costs are required to develop an application specific integrated circuit (ASIC). Additionally, updating or adding features to a design requires the ASIC to be redesigned and refabricated. An alternative to using an ASIC is the field programmable gate array (FPGA). The modern FPGA\u27s ability to be partially reconfigured at runtime allows for the device to have the flexibility normally associated with a processor, while also being able to implement digital logic like in an ASIC. This capability allows for multiple digital functions to be loaded into the device at runtime only as needed. This thesis focuses on developing a reconfigurable framework that enables stream-oriented applications to make more effective use of FPGA resources and to manage partial reconfiguration operations across multiple tasks. This multichannel framework addresses several shortcomings of past research that evaluated various dynamic partial reconfiguration techniques using a color space conversion (CSC) engine. This framework allows for multiple different computations to be performed simultaneously, further improving throughput and flexibility of applications implemented within it. Performance of the system is evaluated by comparing its computational throughput to previous efforts using the CSC engine as well as the performance gained from the flexible scheduling that the framework allows. Implementations using the CSC engine show that performance can be improved up to 5 times faster than previous works, as a result of exploiting parallelism

Silicon Photonic Flex-LIONS for Bandwidth-Reconfigurable Optical Interconnects

This paper reports the first experimental demonstration of silicon photonic (SiPh) Flex-LIONS, a bandwidth-reconfigurable SiPh switching fabric based on wavelength routing in arrayed waveguide grating routers (AWGRs) and space switching. Compared with the state-of-the-art bandwidth-reconfigurable switching fabrics, Flex-LIONS architecture exhibits 21× less number of switching elements and 2.9× lower on-chip loss for 64 ports, which indicates significant improvements in scalability and energy efficiency. System experimental results carried out with an 8-port SiPh Flex-LIONS prototype demonstrate error-free one-to-eight multicast interconnection at 25 Gb/s and bandwidth reconfiguration from 25 Gb/s to 100 Gb/s between selected input and output ports. Besides, benchmarking simulation results show that Flex-LIONS can provide a 1.33× reduction in packet latency and >1.5× improvements in energy efficiency when replacing the core layer switches of Fat-Tree topologies with Flex-LIONS. Finally, we discuss the possibility of scaling Flex-LIONS up to N = 1024 ports (N = M × W) by arranging M^2 W-port Flex-LIONS in a Thin-CLOS architecture using W wavelengths