The next generation of internetworking

This paper describes a research effort concerned with the design of the next generation of internet architecture, which has been necessitated by two emerging trends. First, there will be at least a few orders of magnitude increase in data rates of communication networks in the next few years. For example, researchers are already prototyping networks with data rates of up to a few hundred Mbps, and are planning networks with data rates up to a few Gbps. Second, researchers from all disciplines of science, engineering, and humanities plan to use the communication infrastructure to access widely distributed resources in order to solve bigger and more complex problems. These trends provide new challenges and opportunities to researchers in the communication field. One such challenge is the design of what we call the very high speed internet (VHSI) abstraction which can help efficiently support guaranteed levels of performance for a variety of applications, and can cope with the ever increasing diversity of underlying networks with rapidly growing user population and needs. Our strategy towards achieving this ambitious goal comprises the following:• Design, specification, and prototype implementation of a novel multipoint congram-oriented service that can work well with connection-oriented and datagram high speed networks, can provide variable grade service on a need basis to its applications, and can provide adequate reconfigurability to deal with survivability requirements due to network failures.• Design and implementation of gateway architectures that can support data rates of a few hundred Mbps, can interface with diverse networks, and can implement the congram-oriented service without becoming a performance bottleneck.• Development of analytical and simulation models to evaluate important tradeoffs associated with the design of a congram-oriented protocol, the resource management on diverse networks, and the design of new gateway architectures.

[1]  Deborah Estrin Inter-organization networks: implications of access control: requirements for interconnection protocol , 1986, SIGCOMM '86.

[2]  Stephen E. Deering,et al.  Host groups: A multicast extension to the Internet Protocol , 1985, RFC.

[3]  Guru M. Parulkar,et al.  Towards a framework for high-speed communication in a heterogeneous networking environment , 1989, IEEE Network.

[4]  Andrew S. Tanenbaum,et al.  Computer Networks, Second Edition , 1981 .

[5]  James P. G. Sterbenz,et al.  Axon: Application-Oriented Lightweight Transport Protocol Design , 1989 .

[6]  Eric C. Rosen,et al.  "STUB" Exterior Gateway Protocol , 1984, RFC.

[7]  David L. Mills Exterior Gateway Protocol formal specification , 1984, RFC.

[8]  Jonathan S. Turner,et al.  Design of a broadcast packet switching network , 1988, IEEE Trans. Commun..

[9]  Jonathan S. Turner,et al.  An Architecture for Connection Management in a Broadcast Packet Network , 1987 .

[10]  Alan Huang,et al.  Starlite: a wideband digital switch , 1991 .

[11]  Guru M. Parulkar,et al.  Specification of a multipoint congram-oriented high performance internet protocol , 1990, Proceedings. IEEE INFOCOM '90: Ninth Annual Joint Conference of the IEEE Computer and Communications Societies@m_The Multiple Facets of Integration.

[12]  Van Jacobson,et al.  Congestion avoidance and control , 1988, SIGCOMM '88.

[13]  Kai Y. Eng,et al.  A Knockout Switch for Variable-Length Packets , 1987, IEEE J. Sel. Areas Commun..

[14]  Ross Callon Proposal for a connection-oriented internetwork protocol , 1983, CCRV.

[15]  Jonathan S. Turner,et al.  The Challenge of Multipoint Communication , 1987 .

[16]  James P. G. Sterbenz,et al.  Axon: network virtual storage design , 1990, CCRV.

[17]  Anthony S. Acampora,et al.  The Knockout Switch: A Simple, Modular Architecture for High-Performance Packet Switching , 1987, IEEE J. Sel. Areas Commun..

[18]  Jon Postel,et al.  Internet Control Message Protocol , 1981, RFC.