IJERT-Distribution of Dynamic Routing Protocols (Is-Is, EIGRP, OSPF) in IPv6 Network and Their Performance Analysis (original) (raw)
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Routing of data packets is a critical process on the internet, and routing protocols play a vital role in enabling routers to connect to internetworks using Internet protocols. Internet applications use various routing protocols, such as RIPng, OSPFv3, EIGRPv6, etc., each with its own approach to routing packets. This study presents a basic comparative analysis of as RIPng, OSPFv3, EIGRPv6 protocols. RIPng is an IPv6 routing protocol that allows routers to exchange routing information and calculate the shortest path to a destination based on the number of hops required. OSPFv3 is an IPv6 routing protocol that allows routers to exchange routing information and calculate the shortest path to a destination based on the state of the network links and EIGRPv6 is an IPv6 routing protocol that allows routers to exchange routing information and calculate the shortest path to a destination using both distance-vector and link-state algorithms. The paper "A Comparative Study on Routing Protocols: RIPng, OSPFv3 and EIGRPv6 and Their Analysis Using GNS-3" presents a comparative study on the performance of RIPng, OSPFv3, and EIGRPv6, which are the IPv6 routing protocols equivalent to RIP, OSPF, and EIGRP in IPv4 networks.
Performance Evaluation Of OSPFv3 Routing Protocol On IPv6 Heterogeneous Network
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IPv6 also known as next generation protocol has abundant address space and various advance features to meet varying demands of present and future networks. Once migrated to IPv6, OSPFv3 an IPv6 based Routing Protocol will be first choice among various users to replace its predecessor IPv4 based OSPv2 Routing Protocol. Internet protocol (IP) traffic follows rules established by routing protocols, such as open shortest path first (OSPF). Each router computes shortest paths using weights assigned by the network operator, and creates destination tables used to direct each IP packet to the next router on the path to its final destination. Furthermore, the routing protocol is used to establish procedures to be taken in case of a failure in the network. In this paper, a new genetic algorithm for designing a network with minimal total link capacity is introduced which is necessary to route without overload in case of any single edge or node failure. The real time environment approaches a lo...