A multihomed site is a site that has more than one connection to the public internet with those connections through either the same or different ISPs. Sites choose to multihome for several reasons, especially to improve fault tolerance, perform load balancing, etc. Multihoming today is done largely by having a site obtain a dedicated block of address space and then advertising a route for its prefix through each of its ISP connections. The address block may be from the so-called provider independent space, or may be a sub-allocation from one of its ISPs. A site's ISPs in turn advertise the prefix to some or all of their upstream connections and the route for the prefix may propagate to all of the routers connected to the default-free zone (DFZ). As the number of sites multihoming in this manner increase, the number of routes propagated throughout the DFZ increases and overall routing stability decreases because of the burden on convergence time. This WG will seek alternative approaches with better scaling properties. Specifically, the WG will prefer multihoming solutions that tend to minimise adverse impacts on the end-to-end routing system and limit the number of prefixes that need to be advertised in the Default-Free Zone (DFZ). Just as sites have multiple reasons to choose multihoming, they may have multiple reasons to want to provide these benefits more directly to hosts within their sites, for instance, because some of those hosts may have network stacks capable of detecting and surviving a provider/prefix change. Phasing in hosts with capabilities of multihoming might be part of the Multi6 solution space. In the course of this work, the WG may also study the deeper underlying questions of identity and location of services, hosts and sites as they directly affect multihoming.However, the working group is not chartered to make significant changes to the nature of IP addresses or to inter-domain routing. This WG will consider the problem of how to multihome sites in IPv6. The multihoming approaches currently used in IPv4 can of course be used in IPv6, but IPv6 represents an opportunity for more scalable approaches. IPv6 differs from IPv4 in ways that may allow for different approaches to multihoming that are not immediately applicable to IPv4. For example, IPv6 has larger addresses, hosts support multiple addresses per interface, and relatively few IPv6 address blocks have been given out (i.e., there are no issues with legacy allocations as in IPv4). Also, IPv6 deployment is at an early stage, so modest enhancements to IPv6 could still be proposed. The WG has already produced a document, RFC 3582, on goals for IPv6 site multihoming architectures. It is recognised that this set of goals is ambitious and that some goals may conflict with others. The solution or solutions adopted may only be able to satisfy some of the goals presented there. The WG will take on the following tasks: ======================================== Produce a document describing how multihoming is done today in IPv4, including an explanation of both the advantages and limitations of the approaches. Produce a document outlining practical questions to be considered when evaluating proposals meeting the RFC 3582 goals, including questions concerning upper layer protocols. Produce a document describing the security threats to be addressed by multihoming solutions. Solicit and evaluate specific proposals to multihoming in IPv6 (both existing and new), extract and analyse common architectural features, and select one or a small number of proposals for further development. The architectural analysis will include applications layer considerations and transport layer considerations, as well as lower layer issues. Development of specific solutions will require chartering of work in the appropriate Area or Areas.