NEMO Working Group C. Ng Internet-Draft Panasonic Singapore Labs Expires: April 14, 2006 P. Thubert Cisco Systems M. Watari KDDI R&D Labs F. Zhao UC Davis October 11, 2005 Network Mobility Route Optimization Problem Statement draft-ietf-nemo-ro-problem-statement-01 Status of this Memo By submitting this Internet-Draft, each author represents that any applicable patent or other IPR claims of which he or she is aware have been or will be disclosed, and any of which he or she becomes aware will be disclosed, in accordance with Section 6 of BCP 79. Internet-Drafts are working documents of the Internet Engineering Task Force (IETF), its areas, and its working groups. Note that other groups may also distribute working documents as Internet- Drafts. Internet-Drafts are draft documents valid for a maximum of six months and may be updated, replaced, or obsoleted by other documents at any time. It is inappropriate to use Internet-Drafts as reference material or to cite them other than as "work in progress." The list of current Internet-Drafts can be accessed at http://www.ietf.org/ietf/1id-abstracts.txt. The list of Internet-Draft Shadow Directories can be accessed at http://www.ietf.org/shadow.html. This Internet-Draft will expire on April 14, 2006. Copyright Notice Copyright (C) The Internet Society (2005). Abstract With current Network Mobility (NEMO) Basic Support, all communications to and from Mobile Network Nodes must go through the bi-directional tunnel established between the Mobile Router and Home Ng, et al. Expires April 14, 2006 [Page 1] Internet-Draft NEMO RO Problem Statement October 2005 Agent when the mobile network is away. This results in various inefficiencies associated with packet delivery. This document investigates such inefficiencies, and provides for the motivation behind Route Optimization (RO) for NEMO. Table of Contents 1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . . 3 2. NEMO Route Optimization Problem Statement . . . . . . . . . . 4 2.1. Sub-Optimality with NEMO Basic Support . . . . . . . . . . 4 2.2. Bottleneck in Home Network . . . . . . . . . . . . . . . . 6 2.3. Amplified Sub-Optimality in Nested Mobile Networks . . . . 6 2.4. Sub-Optimality with Combined Mobile IPv6 Route Optimization . . . . . . . . . . . . . . . . . . . . . . . 8 2.5. Security Policy Prohibiting Traffic From Visiting Nodes . 9 2.6. Instability of Communications within a Nested Mobile Network . . . . . . . . . . . . . . . . . . . . . . . . . 9 2.7. Stalemate with a Home Agent Nested in a Mobile Network . . 10 3. Conclusion . . . . . . . . . . . . . . . . . . . . . . . . . . 11 4. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 11 5. Security Considerations . . . . . . . . . . . . . . . . . . . 11 6. Acknowledgments . . . . . . . . . . . . . . . . . . . . . . . 12 7. References . . . . . . . . . . . . . . . . . . . . . . . . . . 13 7.1. Normative Reference . . . . . . . . . . . . . . . . . . . 13 7.2. Informative Reference . . . . . . . . . . . . . . . . . . 13 Appendix A. Change Log . . . . . . . . . . . . . . . . . . . . . 14 Appendix B. Various configurations involving Nested Mobile Networks . . . . . . . . . . . . . . . . . . . . . . 15 B.1. CN located in the fixed infrastructure . . . . . . . . . . 15 B.1.1. Case A: LFN and standard IPv6 CN . . . . . . . . . . . 16 B.1.2. Case B: VMN and MIPv6 CN . . . . . . . . . . . . . . . 16 B.1.3. Case C: VMN and standard IPv6 CN . . . . . . . . . . . 16 B.2. CN located in distinct nested NEMOs . . . . . . . . . . . 17 B.2.1. Case D: LFN and standard IPv6 CN . . . . . . . . . . . 18 B.2.2. Case E: VMN and MIPv6 CN . . . . . . . . . . . . . . . 18 B.2.3. Case F: VMN and standard IPv6 CN . . . . . . . . . . . 18 B.3. CN and MNN located in the same nested NEMO . . . . . . . . 19 B.3.1. Case G: LFN and standard IPv6 CN . . . . . . . . . . . 20 B.3.2. Case H: VMN and MIPv6 CN . . . . . . . . . . . . . . . 20 B.3.3. Case I: VMN and standard IPv6 CN . . . . . . . . . . . 21 B.4. CN located behind the same nested MR . . . . . . . . . . . 21 B.4.1. Case J: LFN and standard IPv6 CN . . . . . . . . . . . 22 B.4.2. Case K: VMN and MIPv6 CN . . . . . . . . . . . . . . . 22 B.4.3. Case L: VMN and standard IPv6 CN . . . . . . . . . . . 23 Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . . 24 Intellectual Property and Copyright Statements . . . . . . . . . . 25 Ng, et al. Expires April 14, 2006 [Page 2] Internet-Draft NEMO RO Problem Statement October 2005 1. Introduction With current Network Mobility (NEMO) Basic Support [1], all communications to and from nodes in a mobile network must go through the bi-directional tunnel established between the Mobile Router and its Home Agent when the mobile network is away. Although such an arrangement allows Mobile Network Nodes to reach and be reached by any node on the Internet , limitations associated to the base protocol degrade overall performance of the network, and, ultimately, can prevent all communications to and from the Mobile Network Nodes. Some of these concerns already exist with Mobile IPv6 [4] and were addressed by the mechanism known as Route Optimization, which is part of the base protocol. With Mobile IPv6, Route Optimization mostly improves the end to end path between Mobile Node and Correspondent Node, with an additional benefit of reducing the load of the Home Network, thus its name. NEMO Basic Support presents a number of additional issues, making the problem more complex, so it was decided to address Route Optimization separately. In that case, the expected benefits are more dramatic, and a Route Optimization mechanism could enable connectivity that would be broken otherwise. In that sense, Route Optimization is even more important to NEMO Basic Support than it is to Mobile IPv6. This document explores limitations inherent in NEMO Basic Support, and their effects on communications between a Mobile Network Node and its corresponding peer. This is detailed in Section 2. It is expected for readers to be familiar with general terminologies related to mobility in [4][2], NEMO related terms defined in [3], and NEMO goals and requirements [5]. Ng, et al. Expires April 14, 2006 [Page 3] Internet-Draft NEMO RO Problem Statement October 2005 2. NEMO Route Optimization Problem Statement In essence, the goal of Route Optimization in NEMO is to reduce limitations and sub-optimalities introduced by the bi-directional tunnel between a Mobile Router and its Home Agent (also known as the MRHA tunnel). In the following sub-sections, we will describe the effects of sub-optimal routing with NEMO Basic Support, how it may cause a bottleneck to be formed in the home network, and how these get amplified with nesting of mobile networks. Closely related to nesting, we will also look into the sub-optimality even when Mobile IPv6 Route Optimization is used over NEMO Basic Support. This is followed by a description of security policy in home network that may forbid transit traffic from Visiting Mobile Nodes in mobile networks. In addition, we will explore the impact of MRHA tunnel on communications between two Mobile Network Nodes on different links of the same mobile network. We will also provide additional motivations for Route Optimization by considering the potential deadlock situation when a Home Agent is part of a mobile network. 2.1. Sub-Optimality with NEMO Basic Support With NEMO Basic Support, all packets sent between a Mobile Network Node and its Correspondent Node are forwarded through the MRHA tunnel, resulting in a sub-optimal path between the two nodes. This sub-optimality has the following undesirable effects: o Longer route leading to increased delay and additional infrastructure load Because a packet must transit from a mobile network to the Home Agent then to the Correspondent Node, the transit time of the packet is usually longer than if the packet were to go straight from the mobile network to the Correspondent Node. When the Correspondent Node (or the mobile network) resides near the Home Agent, the increase in packet delay can be very small. However when the mobile network and the Correspondent Node are relatively near to one another but far away from the Home Agent on the Internet, the increase in delay is very large. Applications such as real-time multimedia streaming may not be able to tolerate such increase in packet delay. In general, the increase in delay may also impact the performance of transport protocols such as TCP, since the sending rate of TCP is partly determined by the round- trip-time (RTT) perceived by the communication peers. Moreover, by using a longer route, the total resource utilization for the traffic would be much higher than if the packets were to follow a direct path between the Mobile Network Node and Ng, et al. Expires April 14, 2006 [Page 4] Internet-Draft NEMO RO Problem Statement October 2005 Correspondent Node. This would result in additional load in the infrastructure. o Increased packet overhead The encapsulation of packets in the MRHA tunnel results in increased packet size due to addition of an outer header. This reduces the bandwidth efficiency, as IPv6 header can be quite substantial relative to the payload for applications such as voice samples. For instance, given a voice application using a 8kbps algorithm (e.g. G.729) and taking a voice sample every 20ms (as in RFC 1889), the packet transmission rate will be 50 packets per second. Each additional IPv6 header is an extra 320 bits per packet (i.e. 16kbps), which is twice the actual payload! o Increased processing delay The encapsulation of packets in the MRHA tunnel also results in increased processing delay at the points of encapsulation and decapsulation. Such increased processing may include encryption/ decryption, topological correctness verifications, MTU computation, fragmentation and reassembly. o Increased chances of packet fragmentation The augmentation in packet size due to packet encapsulation may increase the chances of the packet being fragmented along the MRHA tunnel. This can occur if there is no prior path MTU discovery conducted, or if the MTU discovery mechanism did not take into account the encapsulation of packets. Packets fragmentation will result in a further increase in packet delays, and further reduction of bandwidth efficiency. o Increased susceptibility to link failure Under the assumption that each link has the same probability of link failure, a longer routing path would be more susceptibility to link failure. Thus, packets routed through the MRHA tunnel may be subjected to a higher probability of being lost or delayed due to link failure, compared to packets that traverse directly between the Mobile Network Node and its Correspondent Node. Ng, et al. Expires April 14, 2006 [Page 5] Internet-Draft NEMO RO Problem Statement October 2005 2.2. Bottleneck in Home Network Apart from the increase in packet delay and infrastructure load, forwarding packets through the Home Agent may also lead to either the Home Agent or the Home Link becoming a bottleneck for the aggregated traffic from/to all the Mobile Network Nodes. A congestion at home would lead to additional packet delay, or even packet loss. In addition, Home Agent operations such as security check, packet interception and tunneling might not be as optimized in the Home Agent software as plain packet forwarding. This could further limit the Home Agent capacity for data traffic. Furthermore, with all traffic having to pass through the Home Link, the Home Link becomes a single point of failure for the mobile network. Data packets that are delayed or discarded due to congestion at the home network would cause additional performance degradation to applications. Signaling packets, such as Binding Update messages, that are delayed or discarded due to congestion at the home network, may affect the establishment or update of bi-directional tunnels, causing disruption of all traffic flow through these tunnels. A NEMO Route Optimization mechanism that allows the Mobile Network Nodes to communicate with their Correspondent Nodes via a path that is different from the MRHA tunneling and thereby avoiding the Home Agent, may alleviate or even prevent the congestion at the Home Agent or Home Link. 2.3. Amplified Sub-Optimality in Nested Mobile Networks By allowing other mobile nodes to join a mobile network, and in particular mobile routers, it is possible to form arbitrary levels of nesting of mobile networks. With such nesting, the use of NEMO Basic Support further amplifies the sub-optimality of routing. We call this the amplification effect of nesting, where the undesirable effects of sub-optimal routing with NEMO Basic Support are amplified with each level of nesting of mobile networks. This is best illustrated by an example shown in Figure 1. Ng, et al. Expires April 14, 2006 [Page 6] Internet-Draft NEMO RO Problem Statement October 2005 +--------+ +--------+ +--------+ +--------+ | MR2_HA | | MR3_HA | | MR4_HA | | MR5_HA | +------+-+ +---+----+ +---+----+ +-+------+ \ | | / +--------+ +------------------------------+ | MR1_HA |----| Internet |-----CN1 +--------+ +------------------------------+ | +---+---+ root-MR | MR1 | +-------+ | | +-------+ +-------+ sub-MR | MR2 | | MR4 | +---+---+ +---+---+ | | +---+---+ +---+---+ sub-MR | MR3 | | MR5 | +---+---+ +---+---+ | | ----+---- ----+---- MNN CN2 Figure 1: An example of nested Mobile Network Using NEMO Basic Support, the flow of packets between a Mobile Network Node, MNN, and a Correspondent Node, CN1, would need to go through three separate tunnels, illustrated in Figure 2 below. ----------. ---------/ /----------. -------/ | | /------- MNN -----( - - | - - - | - - - | - - - | - - (------ CN1 MR3-------\ | | \-------MR3_HA MR2--------\ \----------MR2_HA MR1---------MR1_HA Figure 2: Nesting of Bi-Directional Tunnels Ng, et al. Expires April 14, 2006 [Page 7] Internet-Draft NEMO RO Problem Statement October 2005 This leads to the following problems: o Sub-optimal routing Both inbound and outbound packets will flow via the Home Agents of all the Mobile Routers on their paths within the mobile network, with increased latency, less resilience and more bandwidth usage. Appendix B illustrates in detail the packets routes under different nesting configurations of the Mobile Network Nodes. o Increased Packet Size An extra IPv6 header is added per level of nesting to all the packets. The header compression suggested in [6] cannot be applied because both the source and destination (the intermediate Mobile Router and its Home Agent), are different hop to hop. Nesting also amplifies the probability of congestion at the home networks of the upstream Mobile Routers. In addition, the Home Link of each upstream Mobile Router will also be a single point of failure for the nested Mobile Router. 2.4. Sub-Optimality with Combined Mobile IPv6 Route Optimization When a Mobile IPv6 host joins a mobile network, it becomes a Visiting Mobile Node of the mobile network. Packets sent to and from the Visiting Mobile Node will have to be routed not only via the Home Agent of the Visiting Mobile Node, but also via the Home Agent of the Mobile Router in the mobile network. This suffers the same amplification effect of nested mobile network mentioned in Section 2.3. In addition, although Mobile IPv6 [4] allows a mobile host to perform Route Optimization with its Correspondent Node in order to avoid tunneling with its Home Agent, the "optimized" route is no longer optimized when the mobile host is attached to a mobile network. This is because the route between the mobile host and its Correspondent Node is subjected to the sub-optimality introduced by the MRHA tunnel. Interested readers may refer to Appendix B for examples of how the routes will appear with nesting of Mobile IPv6 hosts in mobile networks. The readers should also note that the same sub-optimality would apply when the mobile host is outside the mobile network and its Correspondent Node is in the mobile network. Ng, et al. Expires April 14, 2006 [Page 8] Internet-Draft NEMO RO Problem Statement October 2005 2.5. Security Policy Prohibiting Traffic From Visiting Nodes NEMO Basic Support requires all traffic from visitors to be tunneled to the Mobile Router's Home Agent. This might represent a breach in the security of the home network (some specific attacks against the Mobile Router's binding by rogue visitors have been documented in [7][8]). Administrators might thus fear that malicious packets will be routed into the Home Network via the bi-directional tunnel. As a consequence, it can be expected that in many deployment scenarios, policies will be put in place to prevent unauthorized Visiting Mobile Nodes from attaching to the Mobile Router. However, there are deployment scenarios where allowing unauthorized Visiting Mobile Nodes is actually desirable. For instance, when Mobile Routers attach to other Mobile Routers and form a nested NEMO, they depend on each other to reach the Internet. When Mobile Routers have no prior knowledge of one another (no security association, AAA, PKI etc...), it could still be acceptable to forward packets, provided that the packets are not tunneled back to the Home Networks. A Route Optimization mechanism that allows traffic from Mobile Network Nodes to by-pass the bi-directional tunnel between a Mobile Router and its Home Agent would be a necessary first step towards a Tit for Tat model, where MRs would benefit from a reciprocal altruism, based on anonymity and innocuousness, to extend the Internet infrastructure dynamically. 2.6. Instability of Communications within a Nested Mobile Network Within a nested mobile network, two Mobile Network Nodes may communicate with each other. Let us consider the previous example illustrated in Figure 1 where MNN and CN2 are sharing a communication session. With NEMO Basic Support, a packet sent from MNN to CN2 will need to be forwarded to the Home Agent of each Mobile Router before reaching CN2. Whereas, a packet following the direct path between them need not even leave the mobile network. Readers are referred to Appendix B.3 for detailed illustration of the resulting routing paths. Apart from the consequences of increased packet delay and packet size which are discussed in previous sub-sections, there are two additional effects that are undesirable: o when the nested mobile network is disconnected from the Internet (e.g. MR1 loses its egress connectivity), MNN and CN2 can no longer communicate with each other, even though the direct path from MNN to CN2 is unaffected; Ng, et al. Expires April 14, 2006 [Page 9] Internet-Draft NEMO RO Problem Statement October 2005 o the egress link(s) of the root Mobile Router (i.e. MR1) becomes a bottleneck for all the traffic that is coming in and out of the nested mobile network. A Route Optimization mechanism could allow traffic between two Mobile Network Nodes nested within the same mobile network to follow a direct path between them, without being routed out of the mobile network. This may also off-load the processing burden of the upstream Mobile Routers when the direct path between the two Mobile Network Nodes does not traverse these Mobile Routers. 2.7. Stalemate with a Home Agent Nested in a Mobile Network Several configurations for the Home Network are described in [9]. In particular, there is a mobile home scenario where a (parent) Mobile Router is also a Home Agent for its mobile network. In other words, the mobile network is itself an aggregation of Mobile Network Prefixes assigned to (children) Mobile Routers. A stalemate situation exists in the case where the parent Mobile Router visits one of its children. The child Mobile Router cannot find its Home Agent in the Internet and thus cannot establish its MRHA tunnel and forward the visitors traffic. The traffic from the parent is thus blocked from reaching the Internet and it will never bind to its own (grand parent) Home Agent. Then again, a Route Optimization mechanism that bypasses the nested tunnel might enable the parent traffic to reach the Internet and let it bind. At that point, the child Mobile Router would be able to reach its parent and bind in turn. Additional nested Route Optimization solutions might also enable the child to locate its Home Agent in the nested structure and bind regardless of whether the Internet is reachable or not. Ng, et al. Expires April 14, 2006 [Page 10] Internet-Draft NEMO RO Problem Statement October 2005 3. Conclusion With current NEMO Basic Support, all communications to and from Mobile Network Nodes must go through the MRHA tunnel when the mobile network is away. This results in various inefficiencies associated with packet delivery. This document investigates such inefficiencies, and provides for the motivation behind Route Optimization for NEMO. We have described the effects of sub-optimal routing with NEMO Basic Support, how it may cause a bottleneck to be formed in the home network, and how they get amplified with nesting of mobile networks. These effects will also be seen even when Mobile IPv6 Route Optimization is used over NEMO Basic Support. In addition, other issues concerning the nesting of mobile networks that might provide additional motivation for a NEMO Route Optimization mechanism were also explored, such as the prohibition of forwarding traffic from a Visiting Mobile Node through a MRHA tunnel due to security concerns, the impact of MRHA tunnel on communications between two Mobile Network Nodes on different links of the same mobile network, and the possibility of deadlock when Home Agents are nested within a mobile network. 4. IANA Considerations This is an informational document and does not require any IANA action. 5. Security Considerations This document highlights some limitations of the NEMO Basic Support. In particular, some security concerns could prevent interesting applications of the protocol, as detailed in Section 2.5. Route Optimization for RFC 3963 [1] might introduce new threats, just as it might alleviate existing ones. This aspect will certainly be a key criterion in the evaluation of the proposed solutions. Ng, et al. Expires April 14, 2006 [Page 11] Internet-Draft NEMO RO Problem Statement October 2005 6. Acknowledgments The authors wish to thank the co-authors of previous drafts from which this draft is derived: Marco Molteni, Paik Eun-Kyoung, Hiroyuki Ohnishi, Thierry Ernst, Felix Wu, and Souhwan Jung. In addition, sincere appreciation is also extended to Jari Arkko, Carlos Bernardos, Greg Daley, T.J. Kniveton, Henrik Levkowetz, Erik Nordmark, Alexandru Petrescu, Hesham Soliman, Ryuji Wakikawa and Patrick Wetterwald for their various contributions. Ng, et al. Expires April 14, 2006 [Page 12] Internet-Draft NEMO RO Problem Statement October 2005 7. References 7.1. Normative Reference [1] Devarapalli, V., Wakikawa, R., Petrescu, A., and P. Thubert, "Network Mobility (NEMO) Basic Support Protocol", RFC 3963, January 2005. [2] Manner, J. and M. Kojo, "Mobility Related Terminology", RFC 3753, June 2004. [3] Ernst, T. and H. Lach, "Network Mobility Support Terminology", draft-ietf-nemo-terminology-03 (work in progress), February 2005. 7.2. Informative Reference [4] Johnson, D., Perkins, C., and J. Arkko, "Mobility Support in IPv6", RFC 3775, June 2004. [5] Ernst, T., "Network Mobility Support Goals and Requirements", draft-ietf-nemo-requirements-04 (work in progress), February 2005. [6] Deering, S. and B. Zill, "Redundant Address Deletion when Encapsulating IPv6 in IPv6", draft-deering-ipv6-encap-addr-deletion-00 (work in progress), November 2001. [7] Petrescu, A., "Threats for Basic Network Mobility Support (NEMO threats)", draft-petrescu-nemo-threats-01 (work in progress), January 2004. [8] Jung, S., "Threat Analysis on NEMO Basic Operations", draft-jung-nemo-threat-analysis-02 (work in progress), July 2004. [9] Thubert, P., "NEMO Home Network models", draft-ietf-nemo-home-network-models-03 (work in progress), March 2005. [10] Draves, R., "Default Address Selection for Internet Protocol version 6 (IPv6)", RFC 3484, February 2003. Ng, et al. Expires April 14, 2006 [Page 13] Internet-Draft NEMO RO Problem Statement October 2005 Appendix A. Change Log o draft-ietf-nemo-ro-problem-statement-01: * Added text on effect on TCP contributed by Carlos in Sect 2.1 - "Sub-Optimality with NEMO Basic Support" * Added text on VMN using CoA as source address in Appendix B.4.3 * Re-written Section 2.5 - "Security Policy Prohibiting Traffic From Visiting Nodes" * Replaced "deadlock" with "stalemate" in Section 2.7. * Minor typographical corrections o draft-ietf-nemo-ro-problem-statement-00: * Initial version adapted from Section 1 & 2 of 'draft-thubert-nemo-ro-taxonomy-04.txt' * Added Section 2.2: Bottleneck in the Home Network * Added Section 2.5: Security Policy Prohibiting Traffic From Visiting Nodes * Added Section 2.7: Deadlock with a Home Agent Nested in a Mobile Network * Appendix B extracted from 'draft-watari-nemo-nested-cn-01.txt' Ng, et al. Expires April 14, 2006 [Page 14] Internet-Draft NEMO RO Problem Statement October 2005 Appendix B. Various configurations involving Nested Mobile Networks In the following sections, we try to describe different communication models which involve a nested mobile network, and to clarify the issues for each cases. We illustrate the path followed by packets if we assume nodes only use Mobile IPv6 and NEMO Basic Support mechanisms. Different cases are considered where a Correspondent Node is located in the fixed infrastructure, in a distinct nested mobile network as the Mobile Network Node, or in the same nested mobile network as the Mobile Network Node. Additionally, cases where Correspondent Nodes and Mobile Network Nodes are either standard IPv6 nodes or Mobile IPv6 nodes are considered. As defined in [3], standard IPv6 nodes are nodes with no mobility functions whatsoever, i.e. they are not Mobile IPv6 nor NEMO enabled. This mean that not only can they not move around keeping open connections, but also they cannot process Binding Updates sent by peers. B.1. CN located in the fixed infrastructure The most typical configuration is the case where a Mobile Network Node communicates with a Correspondent Node attached in the fixed infrastructure. Figure 3 below shows an example of such topology. +--------+ +--------+ +--------+ | MR1_HA | | MR2_HA | | MR3_HA | +---+----+ +---+----+ +---+----+ | | | +-------------------------+ | Internet |----+ CN +-------------------------+ | | +---+---+ +--+-----+ root-MR | MR1 | | VMN_HA | +---+---+ +--------+ | +---+---+ sub-MR | MR2 | +---+---+ | +---+---+ sub-MR | MR3 | +---+---+ | ----+---- MNN Figure 3: CN located at the infrastructure Ng, et al. Expires April 14, 2006 [Page 15] Internet-Draft NEMO RO Problem Statement October 2005 B.1.1. Case A: LFN and standard IPv6 CN The simplest case is where both MNN and CN are fixed nodes with no mobility functions. That is, MNN is a Local Fixed Node, and CN is a standard IPv6 node. Packets are encapsulated between each Mobile Router and its respective Home Agent. As shown in Figure 4, in such case, the path between the two nodes would go through: 1 2 3 4 3 2 1 MNN --- MR3 --- MR2 --- MR1 --- MR1_HA --- MR2_HA --- MR3_HA --- CN LFN IPv6 Node The digits represent the number of IPv6 headers. Figure 4: MNN and CN are standard IPv6 nodes B.1.2. Case B: VMN and MIPv6 CN In this second case, both end nodes are Mobile IPv6 enabled mobile nodes, that is, MNN is a Visiting Mobile Node. Mobile IPv6 route optimization may thus be initiated between the two and packets wouldn't go through the Home Agent of the Visiting Mobile Node nor the Home Agent of the Correspondent Node (not shown in the figure). However, packets will still be tunneled between each Mobile Router and its respective Home Agent, in both directions. As shown in Figure 5, the path between MNN and CN would go through: 1 2 3 4 3 2 1 MNN --- MR3 --- MR2 --- MR1 --- MR1_HA --- MR2_HA --- MR3_HA --- CN VMN MIPv6 Figure 5: MNN and CN are MIPv6 mobile nodes B.1.3. Case C: VMN and standard IPv6 CN When the communication involves a Mobile IPv6 node either as a Visiting Mobile Node or as a Correspondent Node, Mobile IPv6 route optimization cannot be performed because the standard IPv6 Correspondent Node cannot process Mobile IPv6 signaling. Therefore, MNN would establish a bi-directional tunnel with its HA, which causes the flow to go out the nested NEMO. Packets between MNN and CN would thus go through MNN's own Home Agent (VMN_HA). The path would therefore be as shown on Figure 6: Ng, et al. Expires April 14, 2006 [Page 16] Internet-Draft NEMO RO Problem Statement October 2005 2 3 4 5 4 MNN --- MR3 --- MR2 --- MR1 --- MR1_HA --- MR2_HA VMN | | 3 1 2 | CN --- VMN_HA --- MR3_HA IPv6 Node Figure 6: MNN is a MIPv6 mobile node and CN is a standard IPv6 node Providing Route Optimization involving a Mobile IPv6 node may require optimization among the Mobile Routers and the Mobile IPv6 node. B.2. CN located in distinct nested NEMOs The Correspondent Node may be located in another nested mobile network, different from the one MNN is attached to, as shown in Figure 7. We define such configuration as "distinct nested mobile networks". +--------+ +--------+ +--------+ +--------+ | MR2_HA | | MR3_HA | | MR4_HA | | MR5_HA | +------+-+ +---+----+ +---+----+ +-+------+ \ | | / +--------+ +-------------------------+ +--------+ | MR1_HA |----| Internet |----| VMN_HA | +--------+ +-------------------------+ +--------+ | | +---+---+ +---+---+ root-MR | MR1 | | MR4 | +---+---+ +---+---+ | | +---+---+ +---+---+ sub-MR | MR2 | | MR5 | +---+---+ +---+---+ | | +---+---+ ----+---- sub-MR | MR3 | CN +---+---+ | ----+---- MNN Figure 7: MNN and CN located in distinct nested NEMOs Ng, et al. Expires April 14, 2006 [Page 17] Internet-Draft NEMO RO Problem Statement October 2005 B.2.1. Case D: LFN and standard IPv6 CN Similar with Case A, we start off with the case where both end nodes do not have any mobility functions. Packets are encapsulated at every mobile router on the way out the nested mobile network, decapsulated by the Home Agents and then encapsulated again on its way down the nested mobile network. 1 2 3 4 3 2 MNN --- MR3 --- MR2 --- MR1 --- MR1_HA --- MR2_HA --- MR3_HA LFN | | 1 1 2 3 2 | CN --- MR5 --- MR4 --- MR4_HA --- MR5_HA IPv6 Node Figure 8: MNN and CN are standard IPv6 nodes B.2.2. Case E: VMN and MIPv6 CN Similar with Case B, when both end nodes are Mobile IPv6 nodes, the two nodes may initiate Mobile IPv6 route optimization. Again, packets will not go through the Home Agent of the MNN nor the Home Agent of the Mobile IPv6 Correspondent Node (not shown in the figure). However, packets will still be tunneled for each Mobile Router to its Home Agent and vise versa. Therefore, the path between MNN and CN would go through: 1 2 3 4 3 2 MNN --- MR3 --- MR2 --- MR1 --- MR1_HA --- MR2_HA --- MR3_HA VMN | | 1 1 2 3 2 | CN --- MR5 --- MR4 --- MR4_HA --- MR5_HA MIPv6 Node Figure 9: MNN and CN are MIPv6 mobile nodes B.2.3. Case F: VMN and standard IPv6 CN Similar to Case C, when the communication involves a Mobile IPv6 node either as a Visiting Mobile Node or as a Correspondent Node, MIPv6 route optimization can not be performed because the standard IPv6 Correspondent Node cannot process Mobile IPv6 signaling. MNN would Ng, et al. Expires April 14, 2006 [Page 18] Internet-Draft NEMO RO Problem Statement October 2005 therefore establish a bi-directional tunnel with its Home Agent. Packets between MNN and CN would thus go through MNN's own Home Agent as shown on figure Figure 10: 2 3 4 5 4 3 MNN --- MR3 --- MR2 --- MR1 --- MR1_HA --- MR2_HA --- MR3_HA VMN | | 2 1 2 3 2 1 | CN --- MR5 --- MR4 --- MR4_HA --- MR5_HA --- VMN_HA IPv6 Node Figure 10: MNN is a MIPv6 mobile node and CN is a standard IPv6 node B.3. CN and MNN located in the same nested NEMO Figure 11 below shows the case where the two communicating nodes are connected behind different Mobile Routers that are connected in the same nested mobile network, and thus behind the same root Mobile Router. Route optimization can avoid packets being tunneled outside the nested mobile network. +--------+ +--------+ +--------+ +--------+ | MR2_HA | | MR3_HA | | MR4_HA | | MR5_HA | +------+-+ +---+----+ +---+----+ +-+------+ \ | | / +--------+ +-------------------------+ +--------+ | MR1_HA |----| Internet |----| VMN_HA | +--------+ +-------------------------+ +--------+ | +---+---+ root-MR | MR1 | +-------+ | | +-------+ +-------+ sub-MR | MR2 | | MR4 | +---+---+ +---+---+ | | +---+---+ +---+---+ sub-MR | MR3 | | MR5 | +---+---+ +---+---+ | | ----+---- ----+---- MNN CN Ng, et al. Expires April 14, 2006 [Page 19] Internet-Draft NEMO RO Problem Statement October 2005 Figure 11: CN and MNN located in the same nested NEMO B.3.1. Case G: LFN and standard IPv6 CN Again, we start off with the case where both end nodes do not have any mobility functions. Packets are encapsulated at every Mobile Router on the way out the nested mobile network via the root Mobile Router, decapsulated and encapsulated by the Home Agents and then make their way back to the nested mobile network through the same root Mobile Router. Therefore, the path between MNN and CN would go through: 1 2 3 4 3 2 MNN --- MR3 --- MR2 --- MR1 --- MR1_HA --- MR2_HA --- MR3_HA LFN | | 1 1 2 3 4 3 2 | CN --- MR5 --- MR4 --- MR1 --- MR1_HA --- MR4_HA --- MR5_HA IPv6 Node Figure 12: MNN and CN are standard IPv6 nodes B.3.2. Case H: VMN and MIPv6 CN Similar with Case B and E, when both end nodes are Mobile IPv6 nodes, the two nodes may initiate Mobile IPv6 route optimization which will avoid the packets to go through the Home Agent of MNN nor the Home Agent of the Mobile IPv6 CN (not shown in the figure). However, packets will still be tunneled between each Mobile Router and its respective Home Agent in both directions. Therefore, the path would be the same with Case G and go through: 1 2 3 4 3 2 MNN --- MR3 --- MR2 --- MR1 --- MR1_HA --- MR2_HA --- MR3_HA LFN | | 1 1 2 3 4 3 2 | CN --- MR5 --- MR4 --- MR1 --- MR1_HA --- MR4_HA --- MR5_HA MIPv6 Node Figure 13: MNN and CN are MIPv6 mobile nodes Ng, et al. Expires April 14, 2006 [Page 20] Internet-Draft NEMO RO Problem Statement October 2005 B.3.3. Case I: VMN and standard IPv6 CN As for Case C and Case F, when the communication involves a Mobile IPv6 node either as a Visiting Mobile Node or as a Correspondent Node, Mobile IPv6 Route Optimization can not be performed. Therefore, MNN will establish a bi-directional tunnel with its Home Agent. Packets between MNN and CN would thus go through MNN's own Home Agent. The path would therefore be as shown on Figure 14: 2 3 4 5 4 3 MNN --- MR3 --- MR2 --- MR1 --- MR1_HA --- MR2_HA --- MR3_HA VMN | | 2 | VMN_HA | | 1 1 2 3 4 3 2 | CN --- MR5 --- MR4 --- MR1 --- MR1_HA --- MR4_HA --- MR5_HA IPv6 Node Figure 14: MNN is a MIPv6 mobile node and CN is a standard IPv6 node B.4. CN located behind the same nested MR Figure 15 below shows the case where the two communicating nodes are connected behind the same nested Mobile Router. The optimization is required when the communication involves MIPv6-enabled nodes. Ng, et al. Expires April 14, 2006 [Page 21] Internet-Draft NEMO RO Problem Statement October 2005 +--------+ +--------+ +--------+ +--------+ | MR2_HA | | MR3_HA | | MR4_HA | | MR5_HA | +------+-+ +---+----+ +---+----+ +-+------+ \ | | / +--------+ +-------------------------+ +--------+ | MR1_HA |----| Internet |----| VMN_HA | +--------+ +-------------------------+ +--------+ | +---+---+ root-MR | MR1 | +---+---+ | +-------+ sub-MR | MR2 | +---+---+ | +---+---+ sub-MR | MR3 | +---+---+ | -+--+--+- MNN CN Figure 15: MNN and CN located behind the same nested MR B.4.1. Case J: LFN and standard IPv6 CN If both end nodes are Local Fixed Nodes, no special function is necessary for optimization of their communication. The path between the two nodes would go through: 1 MNN --- CN LFN IPv6 Node Figure 16: MNN and CN are standard IPv6 nodes B.4.2. Case K: VMN and MIPv6 CN Similar with Case H, when both end nodes are Mobile IPv6 nodes, the two nodes may initiate Mobile IPv6 route optimization. Although few packets would go out the nested mobile network for the Return Routability initialization, however, unlike Case B and Case E, packets will not get tunneled outside the nested mobile network. Therefore, packets between MNN and CN would eventually go through: Ng, et al. Expires April 14, 2006 [Page 22] Internet-Draft NEMO RO Problem Statement October 2005 1 MNN --- CN VMN MIPv6 Node Figure 17: MNN and CN are MIPv6 mobile nodes If the root Mobile Router is disconnected while the nodes exchange keys for the Return Routability procedure, they may not communicate even though they are connected on the same link. B.4.3. Case L: VMN and standard IPv6 CN When the communication involves a Mobile IPv6 node either as a Visiting Mobile Network Node or as a Correspondent Node, Mobile IPv6 Route Optimization cannot be performed. Therefore, even though the two nodes are on the same link, MNN will establish a bi-directional tunnel with it's Home Agent, which causes the flow to go out the nested mobile network. Path between MNN and CN would require another Home Agent (VMN_HA) to go through for this Mobile IPv6 node: 2 3 4 5 4 3 MNN --- MR3 --- MR2 --- MR1 --- MR1_HA --- MR2_HA --- MR3_HA VMN | | 2 | VMN_HA | | 1 1 2 3 4 3 2 | CN --- MR5 --- MR4 --- MR1 --- MR1_HA --- MR2_HA --- MR3_HA IPv6 Node Figure 18: MNN is a MIPv6 mobile node and CN is a standard IPv6 node However, MNN may also decide to use its care-of address as the source address of the packets, thus avoiding the tunneling with the MNN's Home Agent. This is particularly useful for a short-term communication that may easily be retried if it fails. Default Address Selection [10] provides some mechanisms for controlling the choice of the source address. Ng, et al. Expires April 14, 2006 [Page 23] Internet-Draft NEMO RO Problem Statement October 2005 Authors' Addresses Chan-Wah Ng Panasonic Singapore Laboratories Pte Ltd Blk 1022 Tai Seng Ave #06-3530 Tai Seng Industrial Estate Singapore 534415 SG Phone: +65 65505420 Email: chanwah.ng@sg.panasonic.com Pascal Thubert Cisco Systems Technology Center Village d'Entreprises Green Side 400, Avenue Roumanille Biot - Sophia Antipolis 06410 FRANCE Email: pthubert@cisco.com Masafumi Watari KDDI R&D Laboratories Inc. 2-1-15 Ohara Fujimino, Saitama 356-8502 JAPAN Email: watari@kddilabs.jp Fan Zhao University of California Davis One Shields Avenue Davis, CA 95616 US Phone: +1 530 752 3128 Email: fanzhao@ucdavis.edu Ng, et al. Expires April 14, 2006 [Page 24] Internet-Draft NEMO RO Problem Statement October 2005 Intellectual Property Statement The IETF takes no position regarding the validity or scope of any Intellectual Property Rights or other rights that might be claimed to pertain to the implementation or use of the technology described in this document or the extent to which any license under such rights might or might not be available; nor does it represent that it has made any independent effort to identify any such rights. Information on the procedures with respect to rights in RFC documents can be found in BCP 78 and BCP 79. Copies of IPR disclosures made to the IETF Secretariat and any assurances of licenses to be made available, or the result of an attempt made to obtain a general license or permission for the use of such proprietary rights by implementers or users of this specification can be obtained from the IETF on-line IPR repository at http://www.ietf.org/ipr. 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Acknowledgment Funding for the RFC Editor function is currently provided by the Internet Society. Ng, et al. Expires April 14, 2006 [Page 25]