One document matched: draft-oneill-craps-handoff-00.txt
Personal A. O'Neill
G. Tsirtsis
BT
Internet Draft S. Corson
Document: draft-oneill-craps-handoff-00.txt Ansible Systems
Category: Informational August 2000
Expires: February 2001
Generalized IP Handoff
<draft-oneill-craps-handoff-00.txt>
Status of this Memo
This document is an Internet-Draft and is in full conformance with
all provisions of Section 10 of RFC2026. 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
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Internet-Drafts are draft documents valid for a maximum of six
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Abstract
This draft describes a generalized IP handoff model that supports
edge mobility such as that encountered in cellular systems and
Internet roaming. The model is mobile-controlled and network-
constrained. The model is generic in that it permits both planned
and unplanned handoff (i.e. proactive and reactive) and supports
both make-before-break and break-before-make link layers. It also
supports movement within and between technologies, as well as within
and between domains. Finally, it is -equally applicable to routed
mobility and to tunneled mobile IP-based mobility.
O'Neill, Corson, Tsirtsis 1
Internet Draft Generalized IP Handoff August 2000
INDEX
1. Introduction
1.1 Inter-technology Handoff Scenario's. . . . . . . . . . .
2. The Handoff Model
2.1 Handoff Preparation--the Forward protocol. . . . . . . .
2.2 Handoff Completion--the Reverse protocol . . . . . . . .
2.3 Benefits of the Approach. . .. . . . . . . . . . . . . .
3. Legacy Handoff
4. References
1. Introduction
This draft describes a generalized IP handoff model that supports
edge mobility such as that encountered in cellular systems and
Internet roaming. The handoff model is network-constrained/mobile-
controlled. The model is generic in that it permits both planned
and unplanned handoff (i.e. proactive and reactive) and supports
both make-before-break and break-before-make link layers. It also
supports movement within and between technologies, as well as within
and between domains. Finally, it is equally applicable to routed
mobility and to tunneled mobile IP-based mobility. This is necessary
to ensure that intra-domain mobile routing can make use of Mobile IP
services where appropriate and Mobile IP can utilize mobile routing
to limit vertical and direct signalling to the Home Agent, Gateway
Foreign Agent and CN's. It also enables the MN to be isolated from
the mobility support deployment decisions of the domain operator.
Agreement is being reached within the Mobile IP working group that a
'smooth' handoff is one that occurs without packet loss. A 'fast'
handoff is one that occurs with no discernable latency. Here we
define a 'seamless' handoff as one that is both smooth and fast. The
generalized handoff model attempts to support seamless IP handoff.
1.1 Inter-technology Handoff Scenario's
Intra-technology handoff is both well understood and already
supported, especially in the case of cellular systems. A generalized
IP handoff model needs to be both applicable and complementary to
these systems. In addition, there are a number of scenarios in which
an ISP would wish to support a planned handoff between two different
access technologies, especially in the situation where the two
access technologies are attached to the same ISP. In the case of a
change of ISP, which equates to an inter-domain handoff, the
facility is driven by the need for partnerships between single
access owners to compete with the ISP with multiple access services.
Here are some example scenarios to help highlight the need for the
different characteristics of the handoff model advocated by this
O'Neill, Corson, Tsirtsis 2
Internet Draft Generalized IP Handoff August 2000
draft. The model itself, however, is not tied to any specific
scenario and is instead intended to be generic and independent from
specific business cases.
Residential Handoff
A MN is able to access a home network and associated fixed WAN
Internet access infrastructure through either an RF interface
(e.g.: Bluetooth) on a mobile terminal or a network connected
cradle. At the same time the MN has access to cellular resources
that overlap the home network area. Preference may be given to the
home resources due to the improved bandwidth, cost, performance
characteristics. When moving out of range of these home resources
and when subsequently returning home to those resources, the user
would wish to undertake a seamless handoff to maintain application
performance. In the case of a change of ISP it is likely that AAA
processes, middleware-based preferences and user action would all
likely be required to affect this handoff. In the case of an intra-
ISP handoff, service based preferences in the network and MN will
likely be sufficient.
Office Handoff
In this scenario, the user has desktop access to 100Mbit ethernet
and in addition has an 802.11b PCMCIA card which provides access to
scarcer radio resources whilst in transit or away from fixed
resources. When leaving or returning to the desktop facility, the
user would be necessarily plugging and unplugging the fixed ethernet
connection, and the user would wish again to maintain ongoing
application performance without additional activity. Again, it is
clear that some user action is required but the fixed link loss
should be sufficient to automatically trigger the handoff to the
radio layer.
Corporate Handoff
This is an example of an inter-domain handoff and supports the
transition between public resources and corporate resources. The MN
is entering the corporate facilities and is on a call, with the
service being paid for by the corporate on behalf of the user. The
corporate can provide the service cheaper than the public facility
so would wish to trigger a handoff when its staff are in range of
corporate facilities. The handoff should be seamless if possible to
avoid staff simply delaying entering the handoff area whilst on a
call, and hence defeating the aim of reducing cost. Non seamless
handoff may be permissible for specific applications and terminal
types, particularly in exchange for better performance once the
handoff has occurred.
Handoff timing observation
In the general case handoffs should be delayed as their occurrence
increases signalling overhead. Ideally they should only be
undertaken when they decrease the probability of service
interruption. Thus, for example, a MN coming in range of a new AR
does not mean that the MN should immediately handoff to this AR.
Instead, more sophisticated policies accounting for MN-AR Signal
O'Neill, Corson, Tsirtsis 3
Internet Draft Generalized IP Handoff August 2000
Interference Ratio (SIR) levels, MN QoS considerations and AR air
interface loading issues should form the basis of handoff timing. In
some cases "early" handoffs may be required for network efficiency
reasons; in others handoff may be delayed. Equally QoS/service
policy in the MN may require an early handoff to another technology
as in the examples above.
2. The Handoff Model
The handoff model consists of two principle mechanisms--proactive
(or forward) and reactive (or reverse)--that work together to
achieve seamless handoffs. The first mechanism is optional,
preparatory in nature, and can be viewed as a performance
optimization. It may be invoked when either the network (i.e. some
notional network controller entity (NC)) or the mobile host has
advance knowledge of a pending handoff. After this (and possibly
without it), the reverse mechanism is invoked to complete handoff.
This mechanism is always mobile-initiated. The resultant messaging
sequence partially depends upon whether or not the forward mechanism
has occurred.
The handoff model separates the horizontal signalling (dealing with
handoff) from the vertical signalling (dealing with routing) because
there are substantial differences in the vertical plane between
Mobile IP and intra-domain mobile (host) routing solutions, whilst
there is great commonality in the horizontal plane. The horizontal
plane is associated with the desire to locally support the movement
of the MN between the OAR and the NAR using local authentication,
temporary tunneling of packets, and the transfer of critical
protocol state, to the NAR, to minimize service disruption. The
vertical plane either causes a routing update which maintains the
utility of the existing Care of Address (CoA) in the domain by
transferring its route to the NAR, or in the case of MobileIP, the
vertical plane causes a Binding Update to either the Home Agent or
the Gateway Foreign Agent to bind the Home Address (HoA) to the new
CoA at the NAR. Both options are generalised by the Update (UPD) and
Update Acknowledge (UPDack) messages from/to the NAR.
The model is network constrained, mobile controlled such that the
network constrains the MN's choices for the handoff NAR, between
multiple offered NAR's, with the MN being in control of the final
selection. The network is viewed as providing guidance and hints to
the MN as to the timing of the handoff and choices between different
handoff destinations. The timing could vary between 'immediate' in
the case of rapid movement / link degradation, through to
'undefined'. These hints can be triggered autonomously by network
processes that track and manage resources and policies. In addition,
the hints can be triggered by MN handoff requests and actions, which
the network can constrain, modify and/or supplement to enable it
to police and optimize system resources.
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Internet Draft Generalized IP Handoff August 2000
The MN must always ultimately be in control of the handoff. This is
to avoid the inevitable situation in which the network cannot fully
appreciate the application needs and/or personal circumstance of a
user, or user process, at a given time. The user should be able to
view any assistance as providing useful automation that can be
overridden based on local preferences, knowledge or actions. A good
example is in the case of overlapping service areas covered by
multiple disconnected networks, both of which only see their own
view of the situation and would wish to impose conflicting
instructions to a MN. The process of constraining the timing and
handoff locations should be sufficient for the network to protect
and manage its resources whilst enabling the MN to recover from
network control problems and to utilize facilities from multiple
disconnected layer 2 networks.
The full message set is shown in Figure 1.
+----+
| NC | ^ |
+----+ | |
\ ^ (2,4)(3,5)
(0)N-TIN (1)N-HD UPD UPDAck
\ \ | |
v \ | v
+-----+ +-----+
| | ------>(3)HI/HD ----> | |
| OAR | <------(2)HR <------- | NAR |
|_ __| ------>(1)TIN ------> |_ __|
+-----+ +-----+
| ^ ^ | |
| | | | |
|(0)H-TIN (1,3)|(2)
| | H-HR | HH
| | +----+ | | |
| +---------| MN |----------+ | |
+---(1)H-HD-->| |<---(4)HAck--+ |
+----+<--------------+
Fig1: All messages
Entities
NC = Network Controller
OAR = Old Access Router
NAR = New Access Router
MN = Mobile Node
Messages
TIN = Tunnel INitiation
H-TIN = Host TIN
H-HD = Host Handoff Denial
N-TIN = Network TIN
N-HD = Network Handoff Denial
UPD = Update
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Internet Draft Generalized IP Handoff August 2000
UPDAck = UPD Ack
HI = Handoff Initiation
HD = Handoff Denial
HH = Handoff Hint
HR = Handoff Request
H-HR = Host HR
HAck = Handoff Ack
2.1 Handoff Preparation--the Forward protocol
We assume the OAR is receiving the IP flows for delivery over the
old link. The old link is used for data forwarding as long as
necessary (or possible). The forward protocol is initiated by the
"Tunnel INitiation" (TIN) Message and is shown in Figure 2. If
mobile-initiated, the message originates at a mobile host and is
called a "Host Tunnel INitiation" (H-TIN) message. If network-
assisted, the message originates at a NC entity and is called a
"Network Tunnel INitiation" (N-TIN) message. An H-TIN or N-TIN is
sent to the OAR instructing it to prepare for possible handoff to a
NAR. The message might be generated for a number of reasons,
including policy, prior knowledge of movement and other parameters
(outside the scope of this draft) known to the MN or NC. The OAR may
deny either a H-TIN or N-TIN based on local information resulting in
an optional H-HD or N-HD message back to the MN or NC, respectively.
This deny is semantically equivalent to the HD message discussed
later.
Arrival of a H-TIN or N-TIN message at the OAR instructs it to build
a temporary tunnel to the NAR for the possible forwarding of data
packets during handoff. The OAR then sends a TIN message to the
NAR. The TIN effectively conveys the state necessary to achieve
seamless handoff to the NAR. On TIN arrival at the NAR, the NAR
establishes the necessary tunnel and optional buffer state for
possible reception of packets. This tunnel is used if the old link
is lost in either an unpredictable or predictable manner, and
therefore provides both a safety net and an IP layer make-before-
break capability to supplement break-before-make link layers or user
activities. The tunnel transit time and any resultant session / flow
buffering at a NAR can provide additional time for the new link to
be initialized.
The OAR continues to deliver over the old link and may optionally
forward a copy of the data via one or more virtual links to the
potential NAR(s) to assist with seamlessness. The decision to
forward may depend on the H/C-TIN request contents and may be
modified by the OAR based on policy. Here we term the replicated
delivery of packets to multiple NARs for possible forwarding to the
MN as IP diversity. This differs from and should not be confused
with physical radio layer "macro diversity" which is orthogonal to,
but supplemented by IP diversity.
O'Neill, Corson, Tsirtsis 6
Internet Draft Generalized IP Handoff August 2000
+----+
| NC |
+----+
^ \
(0)N-TIN \
\ (1)N-HD
\ v
+-----+ +-----+
| | | |
| OAR | | NAR |
|_ __| ----->(1)TIN -----> |_ __|
+-----+ +-----+
| ^ |
| | |
|(0)H-TIN (2)
| | HH
| | +----+ |
| +---------| MN |<-----------+
+---(1)H-HD-->+----+
Fig2: Forward Messages
The NAR may send a "Handoff Hint" (HH) to the mobile if a layer 3
link to the mobile is present at the NAR. It is triggered by the TIN
and therefore tells the MN that a TIN has succeeded. During movement
it is possible that multiple tunnels may be built to multiple
potential NARs. Some tunnels may be mobile-initiated. Others may
be network-initiated. The mobile may receive multiple hints from
these potential NARs that the network deems suitable for handoff.
The HH is therefore sent from each NAR that the network is prepared
to offer as a handoff point. In a dumb network, this set will be the
same as the set of H-TINs sent by the MN because the network is
unconstrained. In a 'clever' network, the set may be reduced or
modified based on the networks needs.
The HH may report the state of any requirements and facilities
requested by the MN or advertised by the NC. HHs may therefore
include performance and preference information from the network
perspective to assist the MN to rank NARs. If the TIN is MN
initiated, the MN may in addition provide input to this process in
terms of its own preferences and priorities.
A HH can indicate the status of the 'hint' that can range from
mandatory/suggested/optional, and the lifetime of the handoff window
during which this NAR will accept the handoff (immediate, time
window). The associated processing in the MN will depend on the MN
service privileges and the nature of the handoff (inter/intra
domain/technology). The MN may receive mandatory immediate messages
from multiple disconnected control systems with overlapping coverage
which illustrates another case where the MN must be in final charge
to resolve disconnects in network intelligence.
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Internet Draft Generalized IP Handoff August 2000
The HH also indicates whether or not replicated data is available at
the NAR. If the MN requested replication and it was successful, then
replicated packets may be delivered by the NAR to the MN in advance
of handoff as soon as the new link is available. Alternatively it
may only be forwarded after reception of the H-HR at the NAR.
A HH may never arrive due to failures, such as the loss of the TIN.
Therefore the MN can request handoff independently over the new link
(unplanned) on receipt of periodic or locally triggered Agent
Solicitation (AS), Agent Advertisement (AA), Router Solicitation
(RS) and Router Advertisement (RA) messaging.
If the N/C-TIN is rejected for administrative reasons, such as lack
of resources, authorization or any other reason a "Network-Handoff
Denial" (N-HD)or "Host-Handoff Denial" (H-HD ) message may be send
back to the NC or the MN.
2.2 Handoff Completion--the Reverse protocol
The mobile is ultimately responsible for completing handoff. The old
link is used as long as necessary. At some time it determines it
should handoff to a NAR. The timing of this decision is beyond the
scope of this document but will involve both NAR and MN processes.
This handoff may or may not be towards a NAR from which it has
received an HH message. Clearly, the absence/suppression of an HH
from a NAR may indicate that a handoff is not available to that NAR,
and any handoff attempt may therefore fail. A MN should therefore
prioritize NARs advertising an HH above those simply advertising
asynchronous NAR advertisements. Regardless, the mobile initiates
handoff by sending a "Host Handoff Request" (H-HR) to the selected
NAR as shown in Figure 3.
^ |
| |
(4) (5)
UPD UPDAck
| |
| v
+-----+ +-----+
| | ------>(3)HI/HD ----> | |
| OAR | <------(2)HR <------- | NAR |
|_ __| |_ __|
+-----+ +-----+
^ | |
| | |
(1) |(2)
H-HR | HH
+----+ | | |
| MN |----------+ | |
| |<---(4)HAck--+ |
+----+<--------------+
Fig3: Reverse Messages
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Internet Draft Generalized IP Handoff August 2000
On H-HR arrival at the NAR, the NAR checks to see if preparatory
handoff state for the mobile is present (this may include AAA
information and other handoffs-specific state sent in conjunction
with tunnel establishment). If not (in the case of an unplanned
handoff) a Handoff Request (HR) message is sent from the NAR to the
OAR. This message likely carries the mobile's credentials to be
checked at the OAR.
On HR arrival at the OAR, the OAR performs an authentication check
on the mobile. If everything is in order it sends a Handoff
Initiation (HI) to the NAR and creates the forwarding tunnel and
buffer state in both the OAR and the NAR. Otherwise it sends a
Handoff Denial (HD) packet to the NAR. The information carried in a
forward TIN message as well as other information not normally sent
in a TIN (e.g. authorization) comes across in an HI message.
On HI arrival at the NAR, the NAR declares the handoff request a
success and initiates the vertical activity which may include either
a MIP HoA/CoA binding update to the Home Agent/Gateway Foreign Agent
or a routing update in the case of intra-domain mobile routing.
Alternatively on HD arrival at the NAR, the NAR declares handoff
failure. If the mobile has requested handoff notification in its
HHR, the NAR then sends an HAck (or HNack) accordingly.
The above unplanned handoff can be further optimized if the NAR is
in a position to locally authorize and execute the handoff rather
than having to query the OAR for authentication, authorization and
routing/binding information. In this case the NAR can initiate the
horizontal and vertical handoff activity in parallel with each other
so avoiding the round trip delay to the OAR. The OAR to NAR tunnel
is still useful and the completion of the horizontal phase as normal
efficiently manages resources and enables the system to be resilient
to vertical messaging failures and delays.
In the case of a planned handoff, where a successful forward phase
has previously occurred, then the tunnel and handoff state will be
in place at the NAR. The mobile is therefore immediately cleared for
handoff to the NAR which triggers the vertical activity, and a HAck
is returned to the mobile if so requested by the mobile. In
addition, the reverse protocol continues to the OAR to ensure
consistent behavior and state management in all elements independent
of whether the handoff is planned or unplanned.
It can be seen that the de-coupling (asynchronous timing of
messaging and state manipulation) of the forward and reverse phases
enables the MN to recover from forward handoff messaging and network
failures / delays by reverting to an unplanned handoff. The model is
also resilient to vertical messaging problems as the horizontal
tunnel is always installed but often never used.
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Internet Draft Generalized IP Handoff August 2000
2.3 Benefits of the Approach
The approach permits proactively guided/constrained handoff in the
forward direction. This is useful for intra-technology handoffs
(e.g. cellular) where handoff planning is desired for spectrum
efficiency and system load balancing. A NC element can prepare one
or more NARs for handoff and signal the relative desirability of
handoff to these various NARs to the mobile. Ultimately the mobile
must decide to which NAR it will handoff. The network can exert
additional indirect control over mobiles by denying handoffs if
necessary at any time.
3G to WLAN handoff is an example of where a generalized IP handoff
model must be mobile controlled. A 3G network would be unaware of
the existence of the WLAN and of the mobile's desire to perform an
inter-technology handoff.
The mobile-controlled reverse mechanism works on failure of (or in
the absence of) any preparatory forward handoff processing. Thus it
provides a way for a mobile to recover from any failure of planned
handoffs, and to control handoffs across technologies. This
includes movement between wired and unwired technologies.
Establishment of a temporary tunnel from the OAR to NAR effectively
establishes a virtual link to the NAR for data forwarding. On
unexpected loss of the link between the OAR and the mobile, any data
packets hitting the OAR can be tunneled to the NAR for the mobile
(and buffered if necessary while awaiting the mobile's arrival).
This effectively permits layer 3 "make-before-break" operation over
systems that operate at layer 2 in a "break-before-make" mode. This
is accomplished by putting the necessary intelligence only at the
edge routers, and does not rely on intelligent network elements
deeper (or higher) in the network.
The handoff model is orthogonal to the means by which data is routed
to the mobile. Mobile IP [MobileIP], natively-routed micro-mobility
[EMA-MIP,CellularIPdraft,HAWAIIdraft] or some combination of these
schemes may be in use.
2.4 Mapping the Generalized Model to MobileIP
The full message set suggested in this draft is shown in Figure 1
and is mapped to some existing Mobile IP draft messages in table 1.
O'Neill, Corson, Tsirtsis 10
Internet Draft Generalized IP Handoff August 2000
Messages/Draft Proactive PFANE Anchor Smooth EMA:MIP
TIN FBU SHPSH FBUack
H-TIN FBU
N-TIN FBU
HH HORQ FBUack
UPD RREQ RREQ BU UDU
UPDAck RREP RREP BUAck UDUack
HR BU RREQ SHREQ RBUack
HI RREP SHREP RBUack
HD SHREP RBUnack
H-HR RREQ RREQ RREQ SHIN/BU RBU
HAck RREP RREP RREP SHACK RBUAck
Table 1: Generalized IP Handoff Mappings
The original EMA handoff work, covered most recently but
incompletely in the [EMA-MIP] draft reflects all the messages in the
generalized handoff model. In [EMA-MIP] the MIP signalling messages
are used for the horizontal tunnel, state management,
authentication/authorization and error control. This is supplemented
by additional piggybacked messages to convey the EMA routing update
information for the mobile routing update in the vertical plane as a
replacement for the vertical MIP HA/GFA binding updates and
registrations. The EMA:MIP horizontal MIP messaging model uses
existing MIP features in a novel way to provide a comprehensive
handoff model with similarities to other MIP work. For example, the
proactive [Proactive] and PFANE [PFANE] drafts have forward
messaging, but lack a reverse mechanism. The anchor draft [Anchor]
has reverse messaging, but lacks a forward component. The recent
smooth draft [Smooth] has adopted both components, but still lacks
explicit forward messages from the host or NC to initiate handoff,
as well as a message acting as a hint for the mobile to handoff.
The smooth draft also has a different method of signaling
interaction with the NAR, preferring IPv6 tunnels over the IPv6
Routing Option approach used in [EMA:MIP]. Further exploration of
this difference is required to establish the preferred method given
ALL requirements. Table 1 only reflects recent Mobile IP handoff
drafts similar to the generalized model. Others diverge somewhat
from the generalized model. For instance, the fast handoffs draft
[FastHandoffs] has the MN register with the NAR via the OAR which is
acknowledged via the OAR as opposed to the NAR in our model. This
may be a useful optimization in break before make link layers which
do not have a L2 make before break signaling plane (which is not the
case in most cellular systems). Other drafts diverge more
significantly from this generalized model but the reasons for this
divergence is unclear.
O'Neill, Corson, Tsirtsis 11
Internet Draft Generalized IP Handoff August 2000
3. Legacy Handoff
Legacy (cellular) networks support a network controlled handoff
model. This model assumes a relatively "dumb" MN that has no control
over the handoff process and which may, at most, assist in the
handoff procedure. The NC always knows which is the next appropriate
NAR for the MN.
In the model described here, to support such mobiles, the NC can
send a N-TIN to the OAR as shown in Figure 4. The OAR then sends the
TIN to the NAR and sets-up the temporary tunnel for the MN. The TIN
also carries AAA info for the MN so the NAR does not have to
authenticate the MN. The NAR sends an HH to the MN indicating a
mandatory handoff and effectively changes the state of the MN so
that it is now attached to the NAR. In some cases, IP connectivity
between the MN and the NAR has not yet established, in which case
the HH might be send from the OAR over the existing link. At the
same time the NAR can send the UPD in the network to appropriately
reconfigure the routing. This approach may be useful for very small
and unintelligent devices and is supported by the generalized
handoff model.
+----+
| NC | ^ |
+----+ | |
\ (2,4)(3,5)
(0)N-TIN UPD UPDAck
\ | |
\ | v
+-----+ +-----+
| | | |
| OAR | | NAR |
|_ __| ------>(1)TIN ------> |_ __|
+-----+ +-----+
| |
| |
(1) (2)
HH HH
| +----+ |
+--------->| MN | |
+----+<------------+
Fig4: Legacy handoff support
O'Neill, Corson, Tsirtsis 12
Internet Draft Generalized IP Handoff August 2000
4. References
[Anchor] G. Dommety, T. Ye, "Local and Indirect Registration for
Anchoring Handoffs", draft-dommety-mobileip-anchor-handoff-01.txt,
July 2000.
[EMA-MIP] A. O'Neill, S. Corson, G. Tsirtsis, "EMA Enhanced Mobile
IPv6/IPv4", Internet-Draft,draft-oneill-ema-mip-00.txt, July 2000.
[CellularIPdraft] A. Campbell, J. Gomez, C-Y. Wan, Z. Turanyi and
A.Valko, "Cellular IP", Internet-Draft (work in progress), draft-
valko-cellularip-01.txt, October 1999.
[FastHandoffs] K. El Malki, H. Soliman, "Fast Handoffs in Mobile
IPv4", draft-elmalki-mobileip-fast-handoffs-02.txt, July 2000.
[HAWAIIdraft] R. Ramjee, T. La Porta, S. Thuel, K. Varadhan and
L.Salgarelli, ``IP micro-mobility support using HAWAII," Internet-
Draft (work in progress), draft-ietf-mobileip-hawaii-00.txt, June
1999.
[MobileIP] C.E. Perkins, ``IP Mobility Support," Internet RFC 2002,
Oct 1996.
[PFANE] C. Perkins, D. Johnson, "Route Optimization in Mobile IP",
draft-ietf-mobileip-optim-09.txt, February 2000.
[Proactive] J. Kempf, P. Calhoun, "Foreign Agent Assisted Hand-off",
draft-calhoun-mobileip-proactive-fa-00.txt, January 2000.
[Smooth] R. Koodli, C.E. Perkins, " A Framework for Smooth Handovers
with Mobile IPv6", draft-ietf-koodli-smoothv6-00.txt, July 2000.
Author's Addresses
Alan O'Neill
BT
(+44) 1473-646459
alan.w.oneill@bt.com
M. Scott Corson
University of Maryland
Ansible Systems
(+1) 301-405-6630
corson@isr.umd.edu
George Tsirtsis
BT
(+44) 020 88260073
O'Neill, Corson, Tsirtsis 13
Internet Draft Generalized IP Handoff August 2000
george.tsirtsis@bt.com
gtsirt@hotmail.com
O'Neill, Corson, Tsirtsis 14
Internet Draft Generalized IP Handoff August 2000
Copyright Notice
Placeholder for ISOC copyright.
O'Neill, Corson, Tsirtsis 15
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