37 research outputs found
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Indirect interconnection networks for high performance routers/switches
Routers form the backbone of the Internet; their kernel, structure, andconfiguration (scheduler) of the backplane (or switching fabrics) dominate the routers’performance, scalability, reliability and cost. As higher performance is required with therapid development of the network applications, router’s architecture has also evolvedfrom the shared backplane to switched backplane, which mainly uses the indirectinterconnection networks.The indirect interconnection networks include crossbar, MIN (multistageinterconnection networks) and some other irregular topologies. At present, most oftoday’s routers and switches are implemented on single crossbar with symmetric bufferarchitecture. In the first part of this dissertation, we introduce novel asymmetric bufferarchitecture for the crossbar in which a new port and a local shared bus are added. Wethen evaluate its performance and simulate under different bus arbitration and buffermanagement algorithms. Our studies indicate that we can get great improvement for thethroughput and low drop rate. Thus we could save a lot of expensive link bandwidth anddecrease the probability of congestion for the network.Single crossbar complexity increases at O(N2) in terms of crosspoint number,which become unacceptable for scalability as the port number (N) increases. A delta classself-routing MIN with complexity of O(N×log2N) has been widely used in the ATMswitches. But the reduction of crosspoint number results in considerable internal blocking.A number of scalable methods have been proposed to solve this problem. One of themuses more stages with recirculation architecture to reroute the deflected packets, whichgreatly increase the latency. In the second part of this dissertation, we propose aninterleaved multistage switching fabrics architecture and assess its throughput with ananalytical model and simulations. We compare this novel scheme with some previousparallel architectures and show its benefits. From extensive simulations under differenttraffic patterns and fault models, our interleaved architecture achieves better performancethan its counterpart of single panel fabric. Our interleaved scheme achieves speedups(over the single panel fabric) of 3.4 and 2.25 under uniform and hot-spot traffic patterns,respectively at maximum load (p=1). Moreover, the interleaved fabrics show greattolerance against internal hardware failures
Multistage interconnection networks : improved routing algorithms and fault tolerance
Multistage interconnection networks for use by multiprocessor systems are optimal in terms of the number of switching element, but the routing algorithms used to set up these networks are suboptimal in terms of time. The network set-up time and reliability are the major factors to affect the performance of multistage interconnection networks. This work improves routing on Benes and Clos networks as well as the fault tolerant capability. The permutation representation is examined as well as the Clos and Benes networks. A modified edge coloring algorithm is applied to the regular bipartite multigraph which represents a Clos network. The looping and parallel looping algorithms are examined and a modified Tree-Connected Computer is adopted to execute a bidirectional parallel looping algorithm for Benes networks. A new fault tolerant Clos network is presented
Fault tolerant clos network
Multistage interconnection networks, or MINs, provide paths between functional modules in multiprocessor systems. The MINs are usually segmented into several stages. Each stage connects inputs to appropriate links of the next stage so that the cumulative effect of all the stages satisfies input-output connection requirements.
This thesis deals with a fault tolerant Clos network. The fault tolerance technique involves addition of extra switches per stage to compensate for any switch failure The reliability analysis of both ordinary and fault tolerant Clos networks is presented. The optimal number of extra switches required to get the best reliability results has been analyzed
Fault-tolerant interconnection networks for multiprocessor systems
Interconnection networks represent the backbone of multiprocessor systems. A failure in the network, therefore, could seriously degrade the system performance. For this reason, fault tolerance has been regarded as a major consideration in interconnection network design. This thesis presents two novel techniques to provide fault tolerance capabilities to three major networks: the Baseline network, the Benes network and the Clos network.
First, the Simple Fault Tolerance Technique (SFT) is presented. The SFT technique is in fact the result of merging two widely known interconnection mechanisms: a normal interconnection network and a shared bus. This technique is most suitable for networks with small switches, such as the Baseline network and the Benes network. For the Clos network, whose switches may be large for the SFT, another technique is developed to produce the Fault-Tolerant Clos (FTC) network. In the FTC, one switch is added to each stage. The two techniques are described and thoroughly analyzed
A survey of an introduction to fault diagnosis algorithms
This report surveys the field of diagnosis and introduces some of the key algorithms and heuristics currently in use. Fault diagnosis is an important and a rapidly growing discipline. This is important in the design of self-repairable computers because the present diagnosis resolution of its fault-tolerant computer is limited to a functional unit or processor. Better resolution is necessary before failed units can become partially reuseable. The approach that holds the greatest promise is that of resident microdiagnostics; however, that presupposes a microprogrammable architecture for the computer being self-diagnosed. The presentation is tutorial and contains examples. An extensive bibliography of some 220 entries is included
Machine Learning for Multi-Layer Open and Disaggregated Optical Networks
L'abstract è presente nell'allegato / the abstract is in the attachmen
Design study of Software-Implemented Fault-Tolerance (SIFT) computer
Software-implemented fault tolerant (SIFT) computer design for commercial aviation is reported. A SIFT design concept is addressed. Alternate strategies for physical implementation are considered. Hardware and software design correctness is addressed. System modeling and effectiveness evaluation are considered from a fault-tolerant point of view
Analyzing Traffic and Multicast Switch Issues in an ATM Network.
This dissertation attempts to solve two problems related to an ATM network. First, we consider packetized voice and video sources as the incoming traffic to an ATM multiplexer and propose modeling methods for both individual and aggregated traffic sources. These methods are, then, used to analyze performance parameters such as buffer occupancy, cell loss probability, and cell delay. Results, thus obtained, for different buffer sizes and number of voice and video sources are analyzed and compared with those generated from existing techniques. Second, we study the priority handling feature for time critical services in an ATM multicast switch. For this, we propose a non-blocking copy network and priority handling algorithms. We, then, analyze the copy network using an analytical method and simulation. The analysis utilizes both priority and non-priority cells for two different output reservation schemes. The performance parameters, based on cell delay, delay jitter, and cell loss probability, are studied for different buffer sizes and fan-outs under various input traffic loads. Our results show that the proposed copy network provides a better performance for the priority cells while the performance for the non-priority cells is slightly inferior in comparison with the scenario when the network does not consider priority handling. We also study the fault-tolerant behavior of the copy network, specially for the broadcast banyan network subsection, and present a routing scheme considering the non-blocking property under a specific pattern of connection assignments. A fault tolerant characteristic can be quantified using the full access probability. The computation of the full access probability for a general network is known to be NP-hard. We, therefore, provide a new bounding technique utilizing the concept of minimal cuts to compute full access probability of the copy network. Our study for the fault-tolerant multi-stage interconnection network having either an extra stage or chaining shows that the proposed technique provides tighter bounds as compared to those given by existing approaches. We also apply our bounding method to compute full access probability of the fault-tolerant copy network