Distributed Mobility Management N. Tran
Internet-Draft Y. Kim
Intended status: Informational Soongsil University
Expires: 30 December 2024 28 June 2024
Computing Aware Traffic Steering Consideration for Mobile User Plane
Architecture
draft-dcn-dmm-cats-mup-01
Abstract
The document [I-D.draft-mhkk-dmm-srv6mup-architecture] describes the
Mobile User Plane (MUP) architecture for Distributed Mobility
Management. The proposed architecture converts the user mobility
session information from the control plane entity to an IPv6
dataplane routing information. When there are multiple candidate
instances located at different location to serve an user request, the
MUP Provider Edge (PE) might prioritize the closest service location.
However, the closest routing path might not be the optimal route.
This document discusses how the mentioned MUP architecture can be
leveraged to set up dataplane routing paths to the optimal service
instance location with the assistance of computing-aware traffic
steering capabilities. For each session request, based on the up-to-
date collected computing and network information, the MUP controller
can convert the session information to the optimal route.
Status of This Memo
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This Internet-Draft will expire on 30 December 2024.
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Table of Contents
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . 2
2. Terminology used in this draft . . . . . . . . . . . . . . . 3
3. Optimal route configuration procedure of the MUP Architecture
when integrating CATS capabilities . . . . . . . . . . . 4
4. References . . . . . . . . . . . . . . . . . . . . . . . . . 6
4.1. Informative References . . . . . . . . . . . . . . . . . 6
Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . 7
1. Introduction
The document [I-D.draft-mhkk-dmm-srv6mup-architecture] describes the
Mobile User Plane architecture for Distributed Mobility Management.
This architecture is composed of a MUP controller and multiple MUP
PEs. When applying the MUP architecture in 5G network, the MUP PEs
accomodate the N3 RAN network as Interwork Segment or the N6 DN
network as Direct Segment. The MUP PEs advertises the Interwork and
Discovery Segment dataplane network reachability (e.g. Segment
Routing IPv6 segment identifier (SRv6 SID)) to the MUP network via
the interwork and direct segment Discovery routes. Meanwhile, the
MUP controller transformed the received user mobility session
information to the corresponding interwork and direct segment
information. Then, it advertises the transformed information to MUP
PEs via Session Transformed routes. The MUP PEs use the matching
Discovery routes to resolve the Session Transformed routes and
forward the packet through the MUP SRv6 network.
This document discusses the optimal route configuration problem when
applying the mentioned MUP architecture in a network scenario where
an user request can be served by multiple computing instances of the
same service located at different locations. The closest
geographical service location to users might not be the optimal
service instance's location as pointed out in the problem statement
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document of IETF Computing-Aware Traffic Steering (CATS) working
group [I-D.draft-ietf-cats-usecases-requirements]. In this scenario,
an optimal service instance location can be decided at the mobile
control plane or data plane.
In the control plane case, it is possible to use an Application
Function (AF) to determine the optimal service instance and influence
the 5G control plane to select the DN corresponding to the chosen
instance. The MUP-C only needs to transform the optimal DN
information in the session information into the corresponding route.
Meanwhile, in the data plane approach, the MUP-C should decide the
optimal service instance location by itself and transform the
unoptimal session information into the optimal route based on its
decision. The data plane approach can avoid additional signalling
procedure at the control plane of the other approach. It also
supports IP Routing paradigm benefit of SRv6 mobile user plane as
mentioned in the edge computing use case of the document
[I-D.draft-ietf-dmm-srv6mob-arch].
Therefore, a solution to integrate CATS capabilities into the
mentioned MUP architecture is presented in this document. By
considering service computing and network information of all
candidate service instances, the MUP controller can convert the
session information into the optimal dataplane route.
This document is proposed to discuss a possible extension
consideration of the original MUP architecture
document[I-D.draft-mhkk-dmm-srv6mup-architecture]. Regarding the
Distributed Mobility Management requirements described in [RFC7333],
the MUP architecture can partly address the "Non-optimal routes"
problem and the "Multicast considerations" requirement by integrating
CATS capabilties. As described in [RFC4786], anycast is the practice
of making a particular service address available in multiple
locations. Anycast support could be in the scope of multicast
support for distributed mobility management.
2. Terminology used in this draft
CATS-MUP-C: Computing-aware traffic steering MUP-C which integrates
CATS path selection and MUP-C features.
Besides, this document uses the following terminologies which has
been defined in [I-D.draft-ldbc-cats-framework]
CATS: Computing-Aware Traffic Steering takes into account the dynamic
nature of computing resource metrics and network state metrics to
steer service traffic to a service instance.
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Service: An offering that is made available by a provider by
orchestrating a set of resources (networking, compute, storage,
etc.). The same service can be provided in many locations; each of
them constitutes a service instance.
Service instance: An instance of running resources according to a
given service logic.
Service contact instance: A client-facing service function instance
that is responsible for receiving requests in the context of a given
service. A single service can be represented and accessed via
several contact instances that run in different regions of a network.
CATS Path Selector (C-PS): A functional entity that computes and
selects paths towards service locations and instances and which
accommodates the requirements of service requests. Such a path
computation engine takes into account the service and network status
information.
CATS Service Metric Agent (C-SMA): A functional entity that is
responsible for collecting service capabilities and status, and for
reporting them to a C-PS.
CATS Network Metric Agent (C-NMA): functional entity that is
responsible for collecting network capabilities and status, and for
reporting them to a C-PS.
3. Optimal route configuration procedure of the MUP Architecture when
integrating CATS capabilities
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+----------------+
| Mobility |
| Management |
| System |
+----------------+
|
UE Location, Session Info, Service Anycast Address
|
+--------v-------+ *Direct
| CATS-MUP-C | Segment
+----------| +------+ |---------+ community
| | | C-PS | | | S1 Service1
| +----------------+ | +----------+ Contact
UE- | | | C-SMA |/Instance
\+---+ +------+ +-----+ +------+ |----------|\
UE--|RAN|---| PE | |C-NMA| | PE |---| Service | Service2
+---+ +------+ +-----+ +------+ | Site 1 | Contact
UE-/ | | +----------+ Instance
| |
| MUP | Service1
UE- | Network | Contact
\+---+ +------+ +------+ +----------+ Instance
UE--|RAN|---| PE | | PE |---| Service |/
+---+ +------+ +------+ | Site 2 |\Service2
UE-/ | | |----------| Contact
+-------------------------------------+ | C-SMA | Instance
+----------+
*Direct
Segment
community
S2
Figure 1: CATS integrated MUP Architecture with SRv6 dataplane
Figure 1 describes the MUP architecture when integrating with CATS
capabilties. This architecture separates the CATS-based service
instance's location selection from the upper control plane and
integrates to the MUP-C. The optimal route configuration procedure
based on this architecture is described as follows:
Initially, when a service site joins the MUP network, the connecting
MUP-PE advertises the Direct Segment Discovery Route with the direct
segment community value of the service site and the corresponding
SRv6 SID. Different service sites have different direct segment
community values.
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When an UE request a service, during the session establishment
process, the mobility management system provides necessary
information to the MUP-C. Besides session information, UE location
and the requested service anycast address of the session are also
provided.
The controller MUP-C in previous mentioned document is enhanced with
CATS capabilities and renamed to CATS-MUP-C. Application servers
computing and underlay network information are collected by C-SMA and
C-NMA respectively. The sub-component C-PS inside the CATS-MUP-C is
responsible for select optimal service instance's location/service
site to serve the requested anycast service. The decision is based
on the current collected CATS metrics from C-NMA and C-SMA, and UE
location.
Based on this decision, the CATS-MUP-C attaches the corresponding
direct segment community value of the chosen service site to the
Session Transformed route along with the session tunnel endpoint
identifier. The CATS-MUP-C then advertises this Session Transformed
route to the MUP PE connecting to the N3 RAN.
After receiving the Session Transformed route, the MUP PE resolve it
with the Direct Segment Discovery Route that has the matching direct
segment community value. Because this value is the value of the
optimal service site selected by the CATS-MUP-C, the UE packets are
forwarded to the optimal service instance.
Note that the CATS measurement data collection, data delivery
mechansim, and CATS optimal path selection algorithm are in the scope
of CATS, not in this document.
4. References
4.1. Informative References
[I-D.draft-ietf-cats-usecases-requirements]
Yao, K., Trossen, D., Boucadair, M., Contreras, LM., Shi,
H., Li, Y., Zhang, S., and Q. An, "Mobile User Plane
Architecture using Segment Routing for Distributed
Mobility Management", 2 January 2024,
.
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[I-D.draft-ietf-dmm-srv6mob-arch]
Kohno, M., Clad, F., Camarillo, P., Ali, Z., and L. Jalil,
"Architecture Discussion on SRv6 Mobile User plane", Work
in Progress, Internet-Draft, mhkk-dmm-srv6mup-
architecture, 15 February 2024,
.
[I-D.draft-ldbc-cats-framework]
Li, C., Du, Z., Boucadair, M., Contreras, L. M., Drake,
J., Huang, D., and G. S. Mishra, "A Framework for
Computing-Aware Traffic Steering (CATS)", Work in
Progress, Internet-Draft, draft-ldbc-cats-framework-03, 22
June 2023, .
[I-D.draft-mhkk-dmm-srv6mup-architecture]
Matsushima, S., Horiba, K., Khan, A., Kawakami, Y.,
Murakami, T., Patel, K., Kohno, M., Kamata, T., Camarillo,
P., Horn, J., Voyer, D., Zadok, S., Meilik, I., Agrawal,
A., and K. Perumal, "Mobile User Plane Architecture using
Segment Routing for Distributed Mobility Management", Work
in Progress, Internet-Draft, mhkk-dmm-srv6mup-
architecture, 3 March 2024,
.
[RFC4786] Abley, J. and K. Lindqvist, "Operation of Anycast
Services", December 2006,
.
[RFC7333] Chan, H., Liu, D., Seite, P., Yokota, H., and J. Korhonen,
"Requirements for Distributed Mobility Management", August
2014, .
[TS23501] "System architecture for the 5G System (5GS)", December
2023,
.
Authors' Addresses
Minh-Ngoc Tran
Soongsil University
369, Sangdo-ro, Dongjak-gu
Seoul
06978
Republic of Korea
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Email: mipearlska1307@dcn.ssu.ac.kr
Younghan Kim
Soongsil University
369, Sangdo-ro, Dongjak-gu
Seoul
06978
Republic of Korea
Phone: +82 10 2691 0904
Email: younghak@ssu.ac.kr
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