478 research outputs found
A New Addressing and Forwarding Architecture for the Internet
The current Internet routing and addressing architecture is facing a serious scalability problem. The default free zone (DFZ) routing table size grows at an increasing and potentially alarming rate. The Internet architecture uses a single namespace - the IP address, to express two functions about a network entity: its identifier and locator. This overloading of semantics leads to the scalability problem as a consequence of multihoming, traffic engineering, and nonaggregatable address allocations. The current Internet architecture does not inherently support emerging features such as mobility either.
This thesis presents a simple addressing and forwarding architecture (SAFA) for the Internet. SAFA separates the locator namespace from the ID namespace so that the locators can follow the hierarchies in the Internet topology and be aggregated. The locators are allocated dynamically and automatically. The hierarchical format of locators gives end systems more control over the route selection. A straightforward forwarding scheme is designed based on the hierarchical addressing scheme. The meshed part of the Internet topology is integrated into the forwarding procedure through a special forwarding table. With a rendezvous service that maps from IDs to locators, SAFA also provides scalable support for mobility, multihoming and traffic engineering. Our work also includes an Internet topology study and a prototype implementation of the
architecture. The evaluation results suggest that SAFA would be feasible in the current Internet if deployed
A Model for Managing Information Flow on the World Wide Web
Metadata merged with duplicate record (http://hdl.handle.net/10026.1/330) on 20.12.2016 by CS (TIS).This is a digitised version of a thesis that was deposited in the University Library. If you are the author please contact PEARL Admin ([email protected]) to discuss options.This thesis considers the nature of information management on the World Wide Web. The
web has evolved into a global information system that is completely unregulated, permitting
anyone to publish whatever information they wish. However, this information is almost
entirely unmanaged, which, together with the enormous number of users who access it, places
enormous strain on the web's architecture. This has led to the exposure of inherent flaws,
which reduce its effectiveness as an information system.
The thesis presents a thorough analysis of the state of this architecture, and identifies three
flaws that could render the web unusable: link rot; a shrinking namespace; and the inevitable
increase of noise in the system. A critical examination of existing solutions to these flaws is
provided, together with a discussion on why the solutions have not been deployed or adopted.
The thesis determines that they have failed to take into account the nature of the information
flow between information provider and consumer, or the open philosophy of the web. The
overall aim of the research has therefore been to design a new solution to these flaws in the
web, based on a greater understanding of the nature of the information that flows upon it.
The realization of this objective has included the development of a new model for managing
information flow on the web, which is used to develop a solution to the flaws. The solution
comprises three new additions to the web's architecture: a temporal referencing scheme; an
Oracle Server Network for more effective web browsing; and a Resource Locator Service,
which provides automatic transparent resource migration. The thesis describes their design
and operation, and presents the concept of the Request Router, which provides a new way of
integrating such distributed systems into the web's existing architecture without breaking it.
The design of the Resource Locator Service, including the development of new protocols for
resource migration, is covered in great detail, and a prototype system that has been developed
to prove the effectiveness of the design is presented. The design is further validated by
comprehensive performance measurements of the prototype, which show that it will scale to
manage a web whose size is orders of magnitude greater than it is today
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