RFC3574 - Transition Scenarios for 3GPP Networks

Network Working Group J. Soininen, Ed.

Request for Comments: 3574 Nokia

Category: Informational August 2003

Transition Scenarios for 3GPP Networks

Status of this Memo

This memo provides information for the Internet community. It does

not specify an Internet standard of any kind. Distribution of this

memo is unlimited.

Abstract

This document describes different scenarios in Third Generation

Partnership Project (3GPP) defined packet network, i.e., General

Packet Radio Service (GPRS) that would need IP version 6 and IP

version 4 transition. The focus of this document is on the scenarios

where the User Equipment (UE) connects to nodes in other networks,

e.g., in the Internet. GPRS network internal transition scenarios,

i.e., between different GPRS elements in the network, are out of

scope. The purpose of the document is to list the scenarios for

further discussion and study.

Table of Contents

1. IntrodUCtion . . . . . . . . . . . . . . . . . . . . . . . . . 2

2. Scope of the Document. . . . . . . . . . . . . . . . . . . . . 2

3. Brief Description of the 3GPP Network Environment. . . . . . . 2

3.1 GPRS Architecture Basics . . . . . . . . . . . . . . . . . 3

3.2 IP Multimedia Core Network Subsystem (IMS) . . . . . . . . 3

4. Transition Scenarios . . . . . . . . . . . . . . . . . . . . . 5

4.1 GPRS Scenarios . . . . . . . . . . . . . . . . . . . . . . 5

4.2 IMS Scenarios . . . . . . . . . . . . . . . . . . . . . . 8

5. Security Considerations. . . . . . . . . . . . . . . . . . . . 9

6. Contributing Authors . . . . . . . . . . . . . . . . . . . . . 10

7. Acknowledgements . . . . . . . . . . . . . . . . . . . . . . . 10

8. References . . . . . . . . . . . . . . . . . . . . . . . . . . 10

8.1. Normative References . . . . . . . . . . . . . . . . . . 10

8.2. Informative References . . . . . . . . . . . . . . . . . 11

9. Editor's Address . . . . . . . . . . . . . . . . . . . . . . . 11

10. Full Copyright Statement . . . . . . . . . . . . . . . . . . . 12

1. Introduction

This document describes the transition scenarios in 3GPP packet data

networks that might come up in the deployment phase of IPv6. The

main purpose of this document is to identify and to document those

scenarios for further discussion and study them in the v6ops working

group.

Just a brief overview of the 3GPP packet data network, GPRS, is given

to help the reader to better understand the transition scenarios. A

better overview of the 3GPP specified GPRS can be found for example

from [6]. The GPRS architecture is defined in [1].

2. Scope of the Document

The scope is to describe the possible transition scenarios in the

3GPP defined GPRS network where a UE connects to, or is contacted

from, the Internet or another UE. The document describes scenarios

with and without the usage of the SIP-based (Session Initiation

Protocol [5]) IP Multimedia Core Network Subsystem (IMS). The 3GPP

releases 1999, 4, and 5 are considered as the basis.

Out of scope are scenarios inside the GPRS network, i.e., on the

different interfaces of the GPRS network. This document neither

changes 3GPP specifications, nor proposes changes to the current

specifications.

In addition, the possible transition scenarios are described. The

solutions will be documented in a separate document.

All the possible scenarios are listed here. Further analysis may

show that some of the scenarios are not actually relevant in this

context.

3. Brief Description of the 3GPP Network Environment

This section describes the most important concepts of the 3GPP

environment for understanding the transition scenarios. The first

part of the description gives a brief overview to the GPRS network as

such. The second part concentrates on the IP Multimedia Core Network

Subsystem (IMS).

3.1. GPRS Architecture Basics

This section gives an overview to the most important concepts of the

3GPP packet architecture. For more detailed description, please see

[1].

From the point of view of this document, the most relevant 3GPP

architectural elements are the User Equipment (UE), and the Gateway

GPRS Support Node (GGSN). A simplified picture of the architecture

is shown in Figure 1.

The UE is the mobile phone. It can either be an integrated device

comprising a combined GPRS part, and the IP stack, or it might be a

separate GPRS device, and separate equipment with the IP stack, e.g.,

a laptop.

The GGSN serves as an anchor-point for the GPRS mobility management.

It also serves as the default router for the UE.

The Peer node mentioned in the picture refers to a node with which

the UE is communicating.

-- ---- ************ ---------

UE- ... -GGSN--+--* IPv4/v6 NW *--+--Peer node

-- ---- ************ ---------

Figure 1: Simplified GPRS Architecture

There is a dedicated link between the UE and the GGSN called the

Packet Data Protocol (PDP) Context. This link is created through the

PDP Context activation process. During the activation the UE is

configured with its IP address and other information needed to

maintain IP Access, e.g., DNS server address. There are three

different types of PDP Contexts: IPv4, IPv6, and Point-to-Point

Protocol (PPP).

A UE can have one or more simultaneous PDP Contexts open to the same

or to different GGSNs. The PDP Context can be either of the same or

different types.

3.2. IP Multimedia Core Network Subsystem (IMS)

IP Multimedia Core Network Subsystem (IMS) is an architecture for

supporting multimedia services via a SIP infrastructure. It is

specified in 3GPP Release 5. This section provides an overview of

the 3GPP IMS and is not intended to be comprehensive. A more

detailed description can be found in [2], [3] and [4].

The IMS comprises a set of SIP proxies, servers, and registrars. In

addition, there are Media Gateways (MGWs) that offer connections to

non-IP networks such as the Public Switched Telephony Network (PSTN).

A simplified overview of the IMS is depicted in figure 2.

+-------------+ +-------------------------------------+

+------+

S-CSCF---

+------+

+-+ /

SIP Sig. +------+ +------+

----------+------------P-CSCF----------I-CSCF

+------+ +------+

-----------+------------------------------------------------

+--+ User traf.

GPRS access IP Multimedia CN Subsystem

+-------------+ +-------------------------------------+

Figure 2: Overview of the 3GPP IMS architecture

The SIP proxies, servers, and registrars shown in Figure 2 are as

follows.

- P-CSCF (Proxy-Call Session Control Function) is the first

contact point within the IMS for the subscriber.

- I-CSCF (Interrogating-CSCF) is the contact point within an

operator's network for all connections destined to a subscriber

of that network operator, or a roaming subscriber currently

located within that network operator's service area.

- S-CSCF (Serving-CSCF) performs the session control services for

the subscriber. It also acts as a SIP Registrar.

IMS capable UEs utilize the GPRS network as an access network for

accessing the IMS. Thus, a UE has to have an activated PDP Context

to the IMS before it can proceed to use the IMS services. The PDP

Context activation is eXPlained briefly in section 3.1.

The IMS is exclusively IPv6. Thus, the activated PDP Context is of

PDP Type IPv6. This means that a 3GPP IP Multimedia terminal uses

exclusively IPv6 to access the IMS, and the IMS SIP server and proxy

support exclusively IPv6. Hence, all the traffic going to the IMS is

IPv6, even if the UE is dual stack capable - this comprises both

signaling and user traffic.

This, of course, does not prevent the usage of other unrelated

services (e.g., corporate access) on IPv4.

4. Transition Scenarios

This section is divided into two main parts - GPRS scenarios, and

scenarios with the IP Multimedia Subsystem (IMS). The first part -

GPRS scenarios - concentrates on scenarios with a User Equipment (UE)

connecting to services in the Internet, e.g., mail, web. The second

part - IMS scenarios - then describes how an IMS capable UE can

connect to other SIP-capable nodes in the Internet using the IMS

services.

4.1. GPRS Scenarios

This section describes the scenarios that might occur when a GPRS UE

contacts services, or nodes outside the GPRS network, e.g., web-

server in the Internet.

Transition scenarios of the GPRS internal interfaces are outside of

the scope of this document.

The following scenarios are described here. In all of the scenarios,

the UE is part of a network where there is at least one router of the

same IP version, i.e., GGSN, and it is connecting to a node in a

different network.

The scenarios here apply also for PDP Context type Point-to-Point

Protocol (PPP) where PPP is terminated at the GGSN. On the other

hand, where the PPP PDP Context is terminated e.g., at an external

ISP, the environment is the same as for general ISP cases.

1) Dual Stack UE connecting to IPv4 and IPv6 nodes

2) IPv6 UE connecting to an IPv6 node through an IPv4 network

3) IPv4 UE connecting to an IPv4 node through an IPv6 network

4) IPv6 UE connecting to an IPv4 node

5) IPv4 UE connecting to an IPv6 node

1) Dual Stack UE connecting to IPv4 and IPv6 nodes

The GPRS system has been designed in a manner that there is the

possibility to have simultaneous IPv4, and IPv6 PDP Contexts open.

Thus, in cases where the UE is dual stack capable, and in the

network there is a GGSN (or separate GGSNs) that supports both

connections to IPv4 and IPv6 networks, it is possible to connect

to both at the same time. Figure 3 depicts this scenario.

+-------------+

UE +------+

IPv4

------------+ / +------+

IPv6 IPv4 +--------+ /

+-------------+ IPv4 /

------------------------ /

IPv6 GGSN ------------------------------- +-----------+ \ +------+

GPRS Core \ IPv6

+-----------+ +--------+ \

+------+

Figure 3: Dual-Stack Case

However, the IPv4 addresses may be a scarce resource for the

mobile operator or an ISP. In that case, it might not be possible

for the UE to have a globally unique IPv4 address allocated all

the time. Hence, the UE could either activate the IPv4 PDP

Context only when needed, or be allocated an IPv4 address from a

private address space.

2) IPv6 UE connecting to an IPv6 node through an IPv4 network

Especially in the initial stages of IPv6 deployment, there are

cases where an IPv6 node would need to connect to the IPv6

Internet through a network that is IPv4. For instance, this can

be seen in current fixed networks, where the access is provided

via IPv4 only, but there is an IPv6 network deeper in the

Internet. This scenario is shown in Figure 4.

+------+ +------+

+------+

UE ------------------ -----------------

+-----------+ GGSN +---------+ IPv6

IPv6 GPRS Core IPv4 Net

+------+ +-----------+ +------+ +---------+ +------+

Figure 4: IPv6 nodes communicating over IPv4

In this case, in the GPRS system, the UE would be IPv6 capable,

and the GPRS network would provide an IPv6 capable GGSN in the

network. However, there is an IPv4 network between the GGSN, and

the peer node.

3) IPv4 UE connecting to an IPv4 node through an IPv6 network

Further in the future, there are cases where the legacy UEs are

still IPv4 only, capable of connecting only to the legacy IPv4

Internet. However, the GPRS operator network has already been

upgraded to IPv6. Figure 5 represents this scenario.

+------+ +------+

+------+

UE ------------------ -----------------

+-----------+ GGSN +---------+ IPv4

IPv4 GPRS Core IPv6 Net

+------+ +-----------+ +------+ +---------+ +------+

Figure 5: IPv4 nodes communicating over IPv6

In this case, the operator would still provide an IPv4 capable

GGSN, and a connection through the IPv6 network to the IPv4

Internet.

4) IPv6 UE connecting to an IPv4 node

In this scenario, an IPv6 UE connects to an IPv4 node in the IPv4

Internet. As an example, an IPv6 UE connects to an IPv4 web

server in the legacy Internet. In the figure 6, this kind of

possible installation is described.

+------+ +------+

+---+ +------+

UE ------------------ ----- ----

+-----------+ GGSN ? IPv4

IPv6 GPRS Core

+------+ +-----------+ +------+ +---+ +------+

Figure 6: IPv6 node communicating with IPv4 node

5) IPv4 UE connecting to an IPv6 node

This is similar to the case above, but in the opposite direction.

Here an IPv4 UE connects to an IPv6 node in the IPv6 Internet. As

an example, a legacy IPv4 UE is connected to an IPv6 server in the

IPv6 Internet. Figure 7 depicts this configuration.

+------+ +------+

+---+ +------+

UE ------------------ ----- ----

+-----------+ GGSN ? IPv6

IPv4 GPRS Core

+------+ +-----------+ +------+ +---+ +------+

Figure 7: IPv4 node communicating with IPv6 node

4.2. IMS Scenarios

As described in section 3.2, IMS is exclusively IPv6. Thus, the

number of possible transition scenarios is reduced dramatically. In

the following, the possible transition scenarios are listed.

1) UE connecting to a node in an IPv4 network through IMS

2) Two IPv6 IMS connected via an IPv4 network

1) UE connecting to a node in an IPv4 network through IMS

This scenario occurs when an IMS UE (IPv6) connects to a node in

the IPv4 Internet through the IMS, or vice versa. This happens

when the other node is a part of a different system than 3GPP,

e.g., a fixed PC, with only IPv4 capabilities. This scenario is

shown in the Figure 8.

+------+ +------+ +-----+

+---+ +------+

UE -...- ----- IMS -- --

GGSN ? IPv4

IPv6

+------+ +------+ +-----+ +---+ +------+

Figure 8: IMS UE connecting to an IPv4 node

2) Two IPv6 IMS connected via an IPv4 network

At the early stages of IMS deployment, there may be cases where

two IMS islands are only connected via an IPv4 network such as the

legacy Internet. See Figure 9 for illustration.

+------+ +------+ +-----+ +-----+

UE -...- ----- IMS ----------

GGSN +------+ IMS

IPv6 IPv4

+------+ +------+ +-----+ +------+ +-----+

Figure 9: Two IMS islands connected over IPv4

5. Security Considerations

This document describes possible transition scenarios for 3GPP

networks for future study. Solutions and mechanism are explored in

other documents. The description of the 3GPP network scenarios does

not have any security issues.

6. Contributing Authors

This document is a result of a joint effort of a design team. The

members of the design team are listed in the following.

Alain Durand, Sun Microsystems

<Alain.Durand@sun.com>

Karim El-Malki, EriCsson Radio Systems

<Karim.El-Malki@era.ericsson.se>

Niall Richard Murphy, Enigma Consulting Limited

<niallm@enigma.ie>

Hugh Shieh, AT&T Wireless

<hugh.shieh@attws.com>

Jonne Soininen, Nokia

<jonne.soininen@nokia.com>

Hesham Soliman, Ericsson Radio Systems

<hesham.soliman@era.ericsson.se>

Margaret Wasserman, Wind River

<mrw@windriver.com>

Juha Wiljakka, Nokia

<juha.wiljakka@nokia.com>

7. Acknowledgements

The authors would like to thank Basavaraj Patil, Tuomo Sipila, Fred

Templin, Rod Van Meter, Pekka Savola, Francis Dupont, Christine

Fisher, Alain Baudot, Rod Walsh, and Jens Staack for good input, and

comments that helped writing this document.

8. References

8.1. Normative References

[1] 3GPP TS 23.060 v 5.2.0, "General Packet Radio Service (GPRS);

Service description; Stage 2(Release 5)", June 2002.

[2] 3GPP TS 23.228 v 5.3.0, " IP Multimedia Subsystem (IMS); Stage

2(Release 5)", January 2002.

[3] 3GPP TS 24.228 V5.0.0, "Signalling flows for the IP multimedia

call control based on SIP and SDP; Stage 3 (Release 5)", March

2002.

[4] 3GPP TS 24.229 V5.0.0, "IP Multimedia Call Control Protocol based

on SIP and SDP; Stage 3 (Release 5)", March 2002.

[5] Rosenberg, J., Schulzrinne, H., Camarillo, G., Johnston, A.,

Peterson, J., Sparks, R., Handley, M. and E. Schooler, "SIP:

Session Initiation Protocol", RFC3261, June 2002.

8.2. Informative References

[6] Wasserman, M., "Recommendations for IPv6 in Third Generation

Partnership Project (3GPP) Standards", RFC3314, September 2002.

9. Editor's Address

Jonne Soininen

Nokia

313 Fairchild Dr.

Mountain View, CA, USA

Phone: +1-650-864-6794

EMail: jonne.soininen@nokia.com

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