Enhancing performance of conventional computer networks employing selected SDN principles

Hasan, Hasanein

January 2016

This research is related to computer networks. In this thesis, three main issues are addressed which affect the performance of any computer network: congestion, efficient resources utilization and link failure. Those issues are related to each other in many situations. Many approaches have been suggested to deal with those issues as well as many solutions were applied. Despite all the improvements of the technology and the proposed solutions, those issues continue to be a burden on the system’s performance. This effect is related to the increase of the Quality of Service (QoS) requirements in modern networks. The basic idea of this research is evolving the intelligence of a conventional computer network when dealing with those issues by adding some features of the Software Defined Networking (SDN). This adoption upgrades the conventional computer network system to be more dynamic and higher self-organizing when dealing with those issues. This idea is applied on a system represented by a computer network that uses the Open Shortest Path First (OSPF) routing protocol. The first improvement deals with the distribution of Internet Protocol (IP) routed flows. The second improvement deals with tunnel establishment that serves Multi-Protocol Label Switching (MPLS) routed flows and the third improvement deals with bandwidth reservation when applying network restoration represented by Fast Re-route (FRR) mechanism to sooth the effect of link failure in OSPF/MPLS routed network. This idea is also applied on another system that uses the Enhanced Interior Gateway Routing Protocol (EIGRP) to improve the performance of its routing algorithm. Adopting the SDN notion is achieved by adding an intelligent controller to the system and creating a dialog of messages between the controller and the conventional routers. This requires upgrading the routers to respond to the new modified system. Our proposed approaches are presented with simulations of different configurations which produce fine results.

004.6

Performance comparison of two dynamic shared-path protection algorithms for WDM optical mesh networks

Sharma, Ameeth

26 January 2009

Finding an optimal solution to the problem of fast and efficient provisioning of reliable connections and failure recovery in future intelligent optical networks is an ongoing challenge. In this dissertation, we investigate and compare the performance of an adapted shared-path protection algorithm with a more conventional approach; both designed for survivable optical Wavelength Division Multiplexing (WDM) mesh networks. The effect of different classes of service on performance is also investigated. Dedicated path protection is a proactive scheme which reserves spare resources to combat single link failures. Conventional Shared-path Protection (CSP) is desirable due to the efficient utilization of resources which results from the sharing of backup paths. Availability is an important performance assessment factor which measures the probability that a connection is in an operational state at some point in time. It is the instantaneous counterpart of reliability. Therefore, connections that do not meet their availability requirements are considered to be unreliable. Reliability Aware Shared-path Protection (RASP) adopts the advantages of CSP by provisioning reliable connections efficiently, but provides protection for unreliable connections only. With the use of a link disjoint parameter, RASP also permits the routing of partial link disjoint backup paths. A simulation study, which evaluates four performance parameters, is undertaken using a South African mesh network. The parameters that are investigated are: 1. Blocking Probability (BP), which considers the percentage of connection requests that are blocked, 2. Backup Success Ratio (BSR), which considers the number of connections that are successfully provisioned with a backup protection path, 3. Backup Primary Resource Ratio (BPR), which considers the ratio of resources utilized to cater for working traffic to the resources reserved for protection paths and lastly 4. Reliability Satisfaction Ratio (RSR), which evaluates the ratio of provisioned connections that meet their availability requirements to the total number of provisioned connections. Under dynamic traffic conditions with varying network load, simulation results show that RASP can provision reliable connections and satisfy Service Level Agreement (SLA) requirements. A competitive Blocking Probability (BP) and lower Backup Primary Resource Ratio (BPR) signify an improvement in resource utilization efficiency. A higher Backup Success Ratio (BSR) was also achieved under high Quality of Service (QoS) constraints. The significance of different availability requirements is evaluated by creating three categories, high availability, medium availability and low availability. These three categories represent three classes of service, with availability used as the QoS parameter. Within each class, the performance of RASP and CSP is observed and analyzed, using the parameters described above. Results show that both the BP and BPR increase with an increase in the availability requirements. The RSR decreases as the reliability requirements increase and a variation in BSR is also indicated. / Dissertation (MEng)--University of Pretoria, 2009. / Electrical, Electronic and Computer Engineering / unrestricted

Mesh network

Wavelength division multiplexing

Service level agreement

Quality of service

Dynamic traffic

Network recovery

Path availability

Link failure

Blocking probability

Shared-path protection

UCTD

A DISTRIBUTED NETWORK MANAGEMENT AGENT FOR FAULT TOLERANT INDUSTRIAL NETWORKS

Leclerc, Sebastian, Ekrad, Kasra

January 2024

Within industrial systems, dependability is critical to keep the system reliable and available. Faults leading to failures of the whole system must be mitigated by a laborious design, testing, and verification process. This thesis aims to build a Network Management Agent (NMA), capable of fault detection, localization, and recovery in an Ethernet environment. The chosen NMA environment was a distributed industrial system using a redundant controller pair, where the controllers must determine when the roles should switch in case of primary failure. In the industrial context, this role-switching must be bounded and robust enough to withstand mixed traffic classes competing for network resources. An NMA was built to monitor the network with the help of Media Redundancy Protocol (MRP), heartbeats, and industrial switch queue status queries. The NMA could distinguish between node and link failure by localizing the fault while adjusting the network's Quality of Service (QoS). The controllers could safely switch roles after an average difference of 29.7065 ms from the moment the primary failed, and the secondary took over. Link failure was detected in three possible locations within 31.297 ms and the location was found within 373.419 ms. To the authors' best knowledge, other solutions mainly target L3 networks or require specialized supporting technology, whereas MRP was found in the majority of the investigated industrial switches. The proposed solution requires any heartbeat-like function sent from the switch, which MRP offers, and can be generalized to any environment where distinguishing a link from a node failure is important. QoS anomaly detection however requires capable switches and configuration of rules to prioritize the traffic accordingly.

ICN

ICS

DCS

Redundant Controller Pair

Network Fault Monitoring

Link Failure Detection and Localization

QoS Anomaly Detection and Restoration

MRP

Embedded Systems

Inbäddad systemteknik