SFC P. Aranda Gutierrez
Internet-Draft TID
Intended status: Informational M. Gramaglia
Expires: October 6, 2016 IMDEA
DRL. Lopez
TID
W. Haeffner
Vodafone
April 4, 2016

Service Function Chaining Dataplane Elements in Mobile Networks
draft-aranda-sfc-dp-mobile-01

Abstract

The evolution of the network towards 5G implies a challenge for the infrastructure. The targeted services and the full deployment of virtualization in all segments of the network will need service function chains that previously resided in the(local and remote) infrastructure of the Network operators to extend to the radio access network (RAN).

The objective of this draft is to provide a non-exhaustive but representative list of service functions in 4G and 5G networks. We base on the problem statement [RFC7498] and architecture framework [RFC7665] of the SFC working group, as well on the existing mobile networks use cases [I-D.ietf-sfc-use-case-mobility] and the requirement gathering process of the ITU-R IMT 2020 and different initiatives in Europe, Korea and China to anticipate network elements that will be needed in 5G networks.

Status of This Memo

This Internet-Draft is submitted in full conformance with the provisions of BCP 78 and BCP 79.

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This Internet-Draft will expire on October 6, 2016.

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Table of Contents

1. Introduction

TODO: Intro

1.1. Terminology and abbreviations

The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in RFC2119 [RFC2119].

Much of the terminology used in this document has been defined by either the 3rd Generation Partnership Project (3GPP) or by activities related to 5G networks like IMT2020 in ITU-R. Some terms are defined here for convenience, in addition to those found in RFC6459 [RFC6459].

UE User equipment like tablets or smartphones
eNB enhanced NodeB, radio access part of the LTE system
S-GW Serving Gateway, primary function is user plane mobility
P-GW Packet Gateway, actual service creation point, terminates 3GPP mobile network, interface to Packet Data Networks (PDN)
HSS Home Subscriber Server (control plane element)
MME Mobility Management Entity (control plane element)
GTP GPRS (General Packet Radio Service) Tunnel Protocol
S-IP Source IP address
D-IP Destination IP address
IMSI The International Mobile Subscriber Identity that identifies a mobile subscriber
(S)Gi Egress termination point of the mobile network (SGi in case of LTE, Gi in case of UMTS/HSPA). The internal data structure of this interface is not standardized by 3GPP
PCRF 3GPP standardized Policy and Charging Rules Function
PCEF Policy and Charging Enforcement Function
TDF Traffic Detection Function
TSSF Traffic Steering Support Function
IDS Intrusion Detection System
FW Firewall
ACL Access Control List
PEP Performance Enhancement Proxy
IMS IP Multimedia Subsystem
LI Legal Intercept

1.2. General scope of mobile service chains

Current mobile access networks terminate at a mobile service creation point (called Packet Gateway) typically located at the edge of an operator IP backbone. Within the mobile network, the user payload is encapsulated in 3GPP specific tunnels terminating eventually at the P-GW. In many cases application-specific IP traffic is not directly exchanged between the original mobile network, more specific the P-GW, and an application platform, but will be forced to pass a set of service functions. Network operators use these service functions to differentiate their services.

In order to cope with the stringent requirements of 5G networks (cf. Section 1.3), we expect a new architecture to appear. This architecture will surely make extensive use of virtualisation up to the RAN. We also expect that IP packets will need to be processed much earlier that in the current 3GPP architecture. In this context, it is foreseeable that Service Function Chaining will play a substantial role when managing the chains network traffic will traverse. We also expect new kinds of service functions specific to the radio access part to appear and that these new service functions will need to be managed by the SFC management infrastructure of the operator.

1.3. Requirements for 5G networks

As set forth by the 5G Infrastructure Public Private Partenrship (5GPPP), the evolution of the infrastructure towards 5G should enable the following features in the mobile environment:

1.3.1. Evolution of the end-to-end carrier network

[SFC-Mobile-UC] presents the structure of end-to-end carrier networks and focused on the Service Function Chaining use cases for mobile carrier networks, such as current 3GPP- based networks. We recognise that other types of carrier networks that are currently deployed share similarities in the structure of the access networks and the service functions with mobile networks. The evolution towards 5G networks will make the distinction between these different types of networks blur and eventually disappear.

5G networks are expected to massively deploy virtualisation technologies from the radio elements to the core of the network. The four building blocks of the RAN, i.e. i) spectrum allocation or physical layer (PHY), i) Medium Access Control (MAC), iii) Radio Link Control (RLC) and iv) Packet Data Convergence, are candidates for virtualisation.

2. Mobile network overview

[SFC-Mobile-UC] provides an overview of mobile networks up to LTE (Long Term Evolution) networks. As the specifications mature, we will provide the updates to the LTE architecture.

2.1. Building blocks of 4G and 5G networks

The major functional components of an LTE network are shown in Figure 2 and include user equipment (UE) like smartphones or tablets, the LTE radio unit named enhanced NodeB (eNB), the serving gateway (S-GW) which together with the mobility management entity (MME) takes care of mobility and the packet gateway (P-GW), which finally terminates the actual mobile service. These elements are described in detail in [ts-23-401]. Other important components are the home subscriber system (HSS), the Policy and Charging Rule Function (PCRF) and the optional components: the Traffic Detection Function (TDF) and the Traffic Steering Support Function (TSSF), which are described in [ts-23-203]. The P-GW interface towards the SGi-LAN is called the SGi-interface, which is described in [ts-29-061]. The TDF resides on this interface. Finally, the SGi-LAN is the home of service function chains (SFC), which are not standardized by 3GPP.

		  
+--------------------------------------------+
| Control Plane (C)      [HSS]               |  [OTT Appl. Platform]
|                          |                 |             |
|               +--------[MME]       [PCRF]--+--------+ Internet
|               |          |            |    |        |    |
|  [UE-C] -- [eNB-C] == [S-GW-C] == [P-GW-C] |        |    |
+=====|=========|==========|============|====+  +-----+----+-------+
|     |         |          |            |    |  |     |    |       |
|  [UE-U] -- [eNB-U] == [S-GW-U] == [P-GW-U]-+--+----[SGi-LAN]     |
|                                            |  |        |         |
|                                            |  |        |         |
|                                            |  | [Appl. Platform] |
|                                            |  |                  |
| User Plane (U)                             |  |                  |
+--------------------------------------------+  +------------------+          

	      

Source [SFC-Mobile-UC]

Figure 1: End to end context including all major components of an LTE network.

Service Functions handle session flows between mobile user equipment and application platforms. Control plane metadata supporting policy based traffic handling may be linked to individual service functions. In 5G networks, we expect the packet gateway (P-GW) to loose its central position and be integrated with functions in the RAN. Radio Resource Control (RRC) in 5G network will be integrated into the Control Plane environment.

2.1.1. Classification schemes for 5G networks

TBD: We expect classification schemes for 5G networks to evolve as the standards appear.

2.2. Control plane considerations

TBD: We except the RRC to be integrated with the SFC Control plane in 5G.

2.3. Operator requirements

4G mobile operators use service function chains to enable and optimize service delivery, offer network related customer services, optimize network behavior or protect networks against attacks and ensure privacy. Service function chains are essential to their business. Without these, mobile operators are not able to deliver the necessary and contracted Quality of Experience (QoE) or even certain products to their customers.

As set forth by the 5G-PPP [5GPPP], the evolution of the infrastructure towards 5G should enable the following features in the mobile environment:

  • Providing 1000 times higher wireless area capacity
  • Saving up to 90% of energy per service provided
  • Reducing the average service creation time cycle from 90 hours to 90 minutes
  • Facilitating very dense deployments of wireless communication links to connect over 7 trillion wireless

To meet these additional requirements, operators will need to make an extensive use of service chains and to extend their scope to functions in the Radio Access Network.

3. New concepts for network virtualization

Recently, mobile networks showed a clear trends towards virtualisation and softwarization. Introducing them in the architecture of future 5G networks calls for the application of new networking concepts, like:

  • The support for dynamical allocation of Network Functions (NFs) in network nodes
  • The orchestration of Virtual Network Functions (VNFs) according to the requirements of the implemented service

These concepts should be taken as fundamental principles for the design of the future 5G architecture. In the next sections, we present some technical solutions that build upon them.

3.1. Decomposition and Allocation of VNF

The current 3GPP LTE mobile network architecture defines specific units that execute a well-defined set of functions. This allocation is static and determined by the logical architecture of the deployed network. For instance, radio functions are executed in the base stations, while mobility functions are located towards the core of the network. However, according to the guidelines described above, the location process should depend on:

  • the specific requirements of the implemented service,
  • the radio characteristics,
  • the transport network capacity.

The goal of new 5G architectures is to enable different instantiations of the protocol stack. Then each of these instances can be physically located into different entities of the network: near the transmission point or in centralised data centers. Network Functions should hence not be statically located, but their placement should be selected according to different criteria, namely:

  • The increased utilization and reduced amount of resources introduced by centralizing RAN functions,
  • The technology used in the backhaul,
  • The capacity available in the backhaul,
  • The specific requirements of the service in terms of latency, bandwidth and reliability, among others.

3.2. Combining Access and Core

Traditional architectures force a fixed topological relation between network functions, while in a virtualized architecture, as the one proposed above, these constraints are relaxed. This difference is especially highlighted for access and core network functions. While in a traditional architecture, these functions were usually executed in different parts of the network (e.g., the scheduler in the base station and a firewall in the centre of the network), a virtualised architecture blends the boundaries between access and core functions: their final location is decided on a functional basis. For instance, services with strict latency requirements may be located close to the transmission points, while services that can exploit centralisation may be located in the core data centre. The application of this concept may end up with access and core functions sharing the same network location. This fact enables possible improvements, as detailed in the following example. Currently, mobility and scheduling decisions are taken separately. The mobility-related network functions are traditionally located in the core network and their decisions are taken before scheduling ones, which are taken subsequently, in the access network. It is important to note that a decision about mobility cannot be modified at the scheduling level. With a fully virtualised architecture, the mobility and scheduler network functions may be co-located in the same network node, enabling a possible joint-optimization between mobility and scheduling. However, this is only one example of possible optimizations that can be achieved using this kind of approach. The proposed approach reduces high latencies introduced by the traditional access-core deployment. Therefore, further optimisation may be introduced as the impact of signalling protocols is reduced.

3.3. Service-aware orchestration

In order to achieve the advantages described above, there are some challenges that need to be addressed. As new network softwarization techniques allow for the efficient resource sharing across different logical network instances on the same physical infrastructure (i.e., one network share per service), different architectures should be supported simultaneously. Moreover, the orchestration decision of where to locate a specific network function should be taken by considering the peculiarities of each service. These challenges are illustrated by the following examples:

  • Vehicular communications need low latency and sessionless connectivity. Therefore, almost all the VNFs belonging to this service should be located close to the transmission point, including those traditionally located in the core network;
  • Tactile Internet applications require both low latency and session continuity. Therefore, most of the the network functions should be located close to the transmission point, but some control plane ones should be located in the core network;
  • Broadband access users do not usually have strict latency requirements. Thus, the network functions related to them may be located in the core network, efficiently exploiting the multiplexing gain enabled by this kind of deployment.

4. Security Considerations

Organizational security policies must apply to ensure the integrity of the SFC environment.

SFC will very likely handle user traffic and user specific information in greater detail than the current service environments do today. This is reflected in the considerations of carrying more metadata through the service chains and the control systems of the service chains. This metadata will contain sensitive information about the user and the environment in which the user is situated. This will require proper considerations in the design, implementation and operations of such environments to preserve the privacy of the user and also the integrity of the provided metadata.

5. IANA Considerations

This document has no actions for IANA.

6. Acknowledgements

This work has been partially performed in the scope of the SUPERFLUIDITY project, which has received funding from the European Union's Horizon 2020 research and innovation programme under grant agreement No.671566 (Research and Innovation Action). This work has also been partially performed in the framework of the H2020-ICT-2014-2 project 5G NORMA. The authors would like to acknowledge the contributions of their colleagues. This information reflects the consortium's view, but the consortium is not liable for any use that may be made of any of the information contained therein.

7. References

7.1. Normative References

[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate Requirement Levels", BCP 14, RFC 2119, DOI 10.17487/RFC2119, March 1997.
[RFC6459] Korhonen, J., Soininen, J., Patil, B., Savolainen, T., Bajko, G. and K. Iisakkila, "IPv6 in 3rd Generation Partnership Project (3GPP) Evolved Packet System (EPS)", RFC 6459, DOI 10.17487/RFC6459, January 2012.
[RFC7498] Quinn, P. and T. Nadeau, "Problem Statement for Service Function Chaining", RFC 7498, DOI 10.17487/RFC7498, April 2015.
[RFC7665] Halpern, J. and C. Pignataro, "Service Function Chaining (SFC) Architecture", RFC 7665, DOI 10.17487/RFC7665, October 2015.

7.2. Informative References

[I-D.ietf-sfc-use-case-mobility] Haeffner, W., Napper, J., Stiemerling, M., Lopez, D. and J. Uttaro, "Service Function Chaining Use Cases in Mobile Networks", Internet-Draft draft-ietf-sfc-use-case-mobility-05, October 2015.
[ts-23-003] 3GPP, ""Numbering, addressing and identification"", , July 2015.
[ts-23-203] 3GPP, "Policy and charging control architecture", TS 29.203, July 2015.
[ts-23-401] 3GPP, "General Packet Radio Service (GPRS) enhancements for Evolved Universal Terrestrial Radio Access Network (E-UTRAN) access", 3GPP YS 23.401, July 2015.
[ts-29-061] 3GPP, "Interworking between the Public Land Mobile Network(PLMN) supporting packet based services and Packet Data Networks (PDN)", 3GPP TS 29.061, March 2015.
[ts-29-212] 3GPP, "3GPP Evolved Packet System (EPS); Evolved General Packet Radio Service (GPRS) Tunneling Protocol for Control plane (GTPv2-C); Stage 3", 3GPP TS , July 2015.
[ts-29-274] 3GPP, "3GPP Evolved Packet System (EPS); Evolved General Packet Radio Service (GPRS) Tunneling Protocol for Control plane (GTPv2-C); Stage 3", 3GPP 29.274, December 2013.
[ts-29-281] 3GPP, "General Packet Radio System (GPRS) Tunneling ProtocolUser Plane (GTPv1-U)", 3GPP TS , January 2015.
[ts-33-210] 3GPP, "3G security; Network Domain Security (NDS); IP network layer security", 3GPP TS 33.210, December 2012.

Authors' Addresses

Pedro A. Aranda Gutierrez Telefonica, I+D Zurbaran, 12 Madrid, 28010 Spain EMail: pedroa.aranda@telefonica.com
Marco Gramaglia IMDEA Networks Institute Av. Mar Mediterraneo, 22 Leganes, 28911 Spain EMail: marco.gramaglia@imdea.org
Diego R. Lopez Telefonica I+D Zurbaran, 12 Madrid, 28010 Spain EMail: diego@tid.es
Walter Haeffner Vodafone D2 GmbH Ferdinand-Braun-Platz 1 Duesseldorf, 40549 Germany EMail: walter.haeffner@vodafone.com