Utilizing ICN/CCN for Service and VM Migration Support in

Virtualized LTE Systems

Morteza Karimzadeh, Triadimas Satria and Georgios Karagiannis

Department of Computer Science and the Electrical Engineering, University of Twente, Enschede, The Netherlands

Keywords: Virtualized LTE, Service Migration, VM Migration, Service Continuity, ICN/CCN.

Abstract: One of the most important concepts used in mobile networks, like LTE (Long Term Evolution) is service

continuity. A mobile user moving from one network to another network should not lose an on-going service.

In cloud-based (virtualized) LTE systems, services are hosted on Virtual Machines (VMs) that can be moved

and migrated across multiple networks to such locations where these services can be well delivered to

mobile users. The migration of the (1) VMs and (2) the services running on such VMs, should happen in

such a way that the disruption of an on-going service is minimized. In this paper we argue that a technology

that can efficiently be used for supporting service and VM migration is the ICN/CCN (Information Centric

Networking / Content Centric Networking) technology.

1 INTRODUCTION

Long Term Evolution (LTE) is the fourth generation

(4G) technology, which is standardized by the 3rd

Generation Partnership Project (3GPP). It is capable

of providing high data rates as well as support of

high-speed mobility. LTE features low latency in

both the control plane and the user plane, which

creates new opportunities for real-time applications

such as video surveillance, telemedicine, and

distance learning. In the LTE system two main

network parts can be identified which are called

Evolved UMTS Terrestrial Radio Access Network

(e-UTRAN) and the Evolved Packet Core (EPC).

The e-UTRAN consists of base stations denoted as

Evolved Node-Bs (eNodeBs). The EPC is composed

of several network elements. The main important

ones are the Serving Gateway (S-GW), the Packet

Data Network Gateway (P-GW) and the Mobility

Management Entity (MME). The P-GW, that is the

main mobility EPC anchor point, connects the EPC

to other external networks. The S-GW supports the

transport of the user data between the User

Equipment (UE) and the external networks. The

MME is the control node that processes the mobility

management signalling (i.e. handover) between the

UE and the EPC. Even though LTE promises a

faster and more efficient data network, its

architecture is still highly centralized, thus it may

lead to very high bandwidth requirements on core

network equipments. Long communication paths

between users and servers can increase delay and

waste network resources. The Mobile Cloud

Networking (MCN) project (EU FP7 MCN, 2013),

as one of the EU FP7 projects, integrates the use of

cloud computing concepts in LTE mobile networks.

This is accomplished with the objective of

increasing LTE’s performance by building a shared

distributed LTE mobile network that can: (1)

optimize the utilization of computation, storage and

networking resources, (2) minimize communication

delays, (3) avoid bottlenecks, and (4) enable

multiple network operators to create their own

virtual network depending on their requirements and

goals, while using a common physical infrastructure.

The integration of cloud computing concepts in an

LTE system, see (EU FP7 MCN, 2013), can be

realized by: (1) extending the cloud computing

concept beyond the typical (macro) data centers

towards new smaller (micro) data centers that are

distributed within the Radio Access Network (e.g.,

e-UTRAN) and the Mobile Core Network (e.g.,

EPC), see Figure 1, and (2) deploying and running

cloud-based (virtualized) Radio Access Networks,

denoted as RAN as a Service (RANaaS), and Mobile

Core Networks, defined as EPC as a Service

(EPCaaS). This trend is also in line with the

emerging ETSI activities in Network Functions

Virtualization (NFV).

633

Karimzadeh M., Satria T. and Karagiannis G..

Utilizing ICN/CCN for Service and VM Migration Support in Virtualized LTE Systems.

DOI: 10.5220/0004945606330638

In Proceedings of the 4th International Conference on Cloud Computing and Services Science (CLOSER-2014), pages 633-638

ISBN: 978-989-758-019-2

 2014 SCITEPRESS (Science and Technology Publications, Lda.)

Service continuity is a critical issue in mobile

networks implying access to the requested services

without disruption, while the user moves from one

network to another.

MobileEndUser

Radio

Access

Network

DataCenter

FutureMobil eCloudNetworking

Core

Network

CurrentCloudComputing

XaaS

Figure 1: A view of future LTE mobile cellular network.

As illustrated in Figure 2, in cloud based mobile

cellular network systems services are hosted on VMs

that may migrate across multiple physical networks

(i.e. datacentres) with the aim of better service

delivery. A service could be a content delivery or

content generation and manipulation service. The

migration of VMs and the services running on such

VMs should occur in such a way that the disruption

of an on-going service is minimized.

Distributed

Cloud

AccesstoMobile

CloudService



Servicecontinuity



UserMoving

DistributedVirtualizedEPC

DataCenterA

DataCenterB

SeamlessServiceMigration

S/P‐GW

SeamlessVM/FunctionMigration

Virtualized

CoreNetwork

Virtualized

RadioNetwork

S/P‐GW

Figure 2: Service continuity in the virtualized LTE system.

A service continuity solution should be able to

support the migration of services, implying the

support for:

 IP Address Continuity: When a user moves to

another sub-network, the application will not

observe the change of the IP address.

 Session Continuity: It is a combination of IP

address continuity and service context migration.

Service context migration occurs when a user

moves to a new location and the service context

used by the function in the previous location

should be able to be migrated and used by the

same function at the new location.

 Content Continuity: Refers to migration and

delivery of the requested content from a location

close to the mobile user. The requested content

can be migrated and delivered from a location

close to a mobile user.

 Storage Continuity: Storage should be able to

migrate to a new location close to the mobile

user.

 Function Continuity: The same function in a

new location can be run using context used by

the same function in the previous location.

Function migration needs to be supported in

order to maintain function continuity.

Several technologies can be considered as possible

candidates for the support of service and VM

migration in virtualized LTE systems. For example,

live VM migration solutions have been proposed in

the literature, see e.g., (Mandal et al., 2013), but

none of these can be used efficiently to support the

service continuity requirements listed above.

Moreover, in this paper we argue that the best

candidate technology that can efficiently be used for

the support of service and VM migration in

virtualized LTE systems is the Information Centric

Networking/Content Centric Networking (ICN/

CCN). In particular, this paper answers the following

research question:

“Can the ICN/CCN technology be used

efficiently for the support of service and VM

migration in the virtualized LTE?”

This paper is organized as follows. Section 2

provides an overview of the ICN/CCN concept and

explains how it could be exploited to support service

continuity in virtualized LTE systems. Section 3,

briefly introduces other possible candidate

technologies and compares them with the ICN/CCN

approach. Section 4 explains by using an example

how the ICN/CCN concept can be applied in the

virtualized LTE system. Moreover, Sections 3 and 4

are answering the research question listed above.

Finally, Section 5 concludes the article and provides

recommendations for future work.

2 ICN/CCN

ICN is an Internet architecture approach based on

Named Data Objects (NDOs), see e.g., (Ahlgren et

al., 2012), (Pentikousis et al., 2013). It changes the

focal point of the network architecture from the "end

host" to "information" (content or data). The ICN

architecture leverages in-network storage for

caching, multiparty communication through

replication, and interaction models decoupling

senders and receivers (Koponen et al., 2007). The

NDO, such as web page, video, document, or other

kind of information, is independent of the location,

the storage method, the application program, and the

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634

transportation method. A unique name for each

NDO is required in ICN in order to identify objects

independently of their locations. Information about

the source of an object is also useful to associate

with the name. ICN has an API, which is used, as an

interface for publishing or getting NDOs. By using

the ICN API, a producer can publish NDOs to the

Internet and a consumer can get them from internet.

Advantages of the ICN approach could be

summarized as follows (Koponen et al., 2007):

 The ICN approach offers scalable and cost-

effective content distribution as it leverages in-

network caching, so that requests for NDOs can

be served by any network node holding a copy of

the requested NDOs.

 It benefits from persistent and unique naming of

NDOs, and also a service model that decouples

senders and receivers, so that it does not have a

problem with name-object binding.

 The ICN approach has an interesting security

model. It provides name-data integrity and

original verification of NDOs, independently of

the immediate source. Hence, it enables

ubiquitous caching with retained name-data

integrity and authenticity.

 The ICN approach supports IP address continuity

and multi-homing. A mobile client just needs to

send requests for NDOs to a new access and the

requests will be served by a network node that

might be different from the previous network

node.

 The ICN approach provides better reliability and

performance compared to the current networks

since it leverages optimized hop-by-hop

transport and in-network caching.

Currently there are several ICN approaches that have

been developed, such as Data-Oriented Network

Architecture (DONA) (Koponen et al., 2007),

Content-Centric Networking (CCN) (Jacobson et al,

2009), Publish-Subscribe Internet Routing Paradigm

(PSIRP) (Fotiou et al., 2012), Network of

Information (NetInf) (Dannewitz et al., 2013) and

Translating Relaying Internet Architecture

integrating Active Directories (TRIAD) (Gritter and

Cheriton, 2000). These ICN approaches undergo the

lack of efficient support of session and function

continuity. However, the Service-Centric

Networking (SCN) (Braun et al., 2011) concept,

which is a new ICN based concept is able to support

session and function continuity. SCN is a new

networking paradigm for the future Internet, in

which routing and forwarding are based on service

identifiers. SCN is an extension of CCN, see Section

2.1, which is designed based on an object-oriented

approach, in which the contents and the services are

considered as objects. In SCN, the content not only

can be retrieved but also can be processed before

being delivered to users. In SCN, services are

represented as functions to be invoked by users. By

using an object-oriented approach, both functions

and data are integrated into objects. In SCN, clients

can request for both services and contents by using

object names.

2.1 CCN Concept

The transport protocol used in CCN (Jacobson et al.,

2009) is called CCNx that is used to distribute

information related to the location of NDOs

published on nodes. There are two types of CCNx

messages, namely the Interest message, which

contains the request for an NDO and the Data

message, which contains the response for an Interest

message.

a. Interest message processing b. Data forwarding

Figure 3: CCN protocol Overview.

The CCNx protocol, see Figure 3, operates based

on three main data structures as follows:

 Content Store (CS): CS represents a buffer

memory used for data retrieval by prefix match

lookup on names.

 Forwarding Information Base (FIB): FIB

contains a list of entries with interfaces to where

the Interest messages should be forwarded. Each

entry in the FIB may point to multiple interfaces

to where the Interest messages could be

forwarded.

 Pending Interest Table (PIT): PIT is used to

keep track of Interest messages forwarded

upstream. It contains information of sources of

unsatisfied Interests. Each entry in the PIT may

point to multiple sources.

Start

Receive a Interest

message

Exist in

Content Store?

Exist in PIT?

Exist in FIB?

End

Send data through

the arrival face

Add the arrival face to

the existing PIT entry

Add a new PIT entry

Send the Interest through

the outgoing face

Yes

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3 MOTIVATION: WHY ICN/CCN

SHOULD BE USED FOR

SERVICE AND VM

MIGRATION SUPPORT IN

VIRTUALIZED LTE SYSTEMS

This section introduces other possible candidate

technologies for service and VM migration support

and analyses and compares them with the ICN/CCN

approach in order to verify whether they can be

applied in a virtualised LTE system.

3.1 Mobile Content Distribution

Networks (M-CDN)

The deployment and distribution of cache servers in

the Internet, enables the distribution of load in

serving the increasing number of requests of content,

such as web content, video content or software.

Current caching products can be deployed solely

outside a mobile operator’s network, such as the

solutions offered by Akamai (Nygren et al., 2010),

or close to/at the mobile operator’s gateways that

support mobility anchor functionality. The aim of

M-CDN, see e.g., (Saroiu et al., 2002), is to integrate

cache servers with the mobile operator’s core

network or even with its access and backhaul

network in order to move these cache servers, as

content sources, closer to mobile users.

3.2 Software-Defined Networking

(SDN)

Open Networking Foundation (ONF) defined SDN

as an emerging network architecture where network

control is decoupled from forwarding and is directly

programmable (

ONF, April 2012). The SDN

architecture supports network virtualization since the

underlying network infrastructure can be abstracted

from the applications and network services. It

provides a new dynamic network architecture, which

changes traditional network platforms into rich

service-delivery platforms. In practice, SDN refers

more broadly to logically centralized software

control. The network appears to the applications and

policy engines as a single logical switch since the

network intelligence that maintains a global view of

the network is logically centralized in software-

based SDN controllers.

3.3 Host Identity Protocol (HIP)

HIP introduces a new layer between the network and

transport layers, which maps the host identifiers to

network addresses and vice versa (Moskowitz and

Nikander, 2006). In the HIP architecture, the end-

point names and locators, which are both

represented by IP addresses in the current Internet

architecture, are separated. IP addresses will act as

locators, while the host identifiers take the role of

end-point identifiers. The existence of Host Identity

Layer ensures that the transport layer connections

are no more bound to IP addresses, so that if the

location of a host changes, the connections will not

have to be broken.

3.4 SCTP with Dynamic Address

Reconfiguration Extension

T. Dreibholz in (Dreibholz et al., 2003) proposed a

new scheme for mobility management for IP-based

networks relying on a transport protocol called

Stream Control Transmission Protocol (SCTP), with

the extension for dynamic address reconfiguration,

and the Reliable Server Pooling (RSerPool) protocol

suite. The proposed solution is transparent to

application, and does not require changes in the

network infrastructure. SCTP, specified in IETF

RFC 4960, is a transport protocol that provides a

more flexible data delivery by separating reliable

transfer of messages between endpoints from the

actual delivery to the user process. It supports multi-

homed endpoints with more than one IP address, so

that it provides an improved network-level fault

tolerance.

3.5 Proxy Mobile Ipv6 (PMIpv6)

PMIPv6 is a network-based mobility management

protocol (Gundavelli et al., 2008) based on the

Mobile IPv6 concept, specified in IETF RFC 3775,

which is designed to provide mobility management

support to a mobile node without requiring

participation of the mobile node in any IP mobility

related signalling. There are two core functional

entities in PMIPv6 used to track movements of

mobile nodes and initiate the mobility signalling and

set up the required routing state, namely Local

Mobility Anchor (LMA) and Mobile Access

Gateway (MAG). The LMA is the topological

anchor point for the mobile node’s home network

prefixes used to maintain a reachability state of the

mobile node, while the MAG is the entity used to

perform mobility management for the node attached

to its access link.

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3.6 Identifier-Locator Network

Protocol (ILNP)

Randall Atkinson in (Atkinson et al., 2009) proposed

the ILNP, a naming architecture which addresses

issues of mobility, multi-homing, and end-to-end IP

security. It evolves the naming in the Internet by

splitting an address into two different entities, as

Identifier (I) used for end-to-end identity and

Locator (L) used for routing and forwarding packets.

It provides an integrated solution to the issues

mentioned above without changing the core routing

architecture, while offering incremental deploy-

ability through backward compatibility with IPv6.

3.7 Analysis and Comparison

To support service continuity in virtualised LTE

systems, the selected technology needs to support

requirements, such as IP address continuity, session

continuity, content continuity, storage continuity and

function continuity, see Section 1. Table 1 analyses

and compares ICN/CCN with other candidate

technologies that were briefly described in the

previous subsections, taking into account the

requirements listed in Section 1.

Table 1: The list of solutions and their ability in

supporting service continuity (S: Supported, NS: Not

Supported).

Solutions /

Approaches

IP Address

Continuity

Session

Continuity

Content

Continuity

Storage

Continuity

Function

Continuity

ICN

S S S S S

M-CDN

S S S S NS

SDN

S S S S S

HIP

S NS NS NS NS

SCTP

S NS NS NS NS

PMIPv6

S NS NS NS NS

ILNP

S NS NS NS NS

Based on the analysis and comparison given in

Table 1, it can be deduced that the ICN/CCN and

SDN solutions can satisfy all requirements for

service continuity. This also implies that the

ICN/CCN technology is a promising candidate that

can efficiently be used for the support of service and

VM migration in the virtualized LTE system. The

proposed ICN/CCN approach could also offer

reliable, scalable and cost-effective content

distribution by leveraging in-network caching. This

solution may be integrated with the SDN approach,

by utilizing OpenFlow switches in order to provide a

dynamic network architecture that fosters network

virtualization and can improve network scalability,

manageability and agility. The centralized network

state in the control layer provides simplicity and

flexibility for network designers and network

operators to configure and improve their networks

using automated SDN programs. However, the

deployment of SDN requires significant changes on

the existing network infrastructure.

4 EXAMPLE OF INTEGRATING

ICN/CCN IN A VIRTUALIZED

LTE SYSTEM

This section provides an example on how the

ICN/CCN concept can be applied in a virtualized

LTE system. As shown in Figure 4, the assumption

in this architecture is that the eNodeBs, S-GWs and

P-GWs are CCN capable (i.e., able to support the

CCNx protocol) and that the routers deployed in the

infrastructure used to interconnect the RAN and

EPC components are non CCN capable.

Furthermore, it is also considered that the

Content Delivery Network (CDN) engine/ repository

is CCN capable and could provide the requested

content/data to the CCN infrastructure faster than the

main server that stores the content. Utilizing the

CDN repository could effectively accelerate the

content delivery to users and reduce bandwidth

consumption in the network.

In this figure Virtualization Controlling Platform

(VCP) represents the cloud components, which carry

out the signalling and configuration of the

virtualized LTE elements (e.g., eNodeBs, S-GWs

and P-GWs) in order to support service continuity,

see (EU FP7 MCN, 2013).

It is also considered that UEs are CCN capable,

meaning that they are able to generate, send and

receive the Interest and Data messages.

IProuters

S‐GW+CCN

eNodeB+CCN

Movi ng

Handovering

P‐GW+CCN

Int er net

Content

Server(CCN)

CDNEngine

VCP

Figure 1: Integrating ICN/CCN in LTE system.

When a UE that uses both a service and a

virtualized CCN process hosted on a (source) data

centre, moves towards another (destination) data

centre hostsing another virtualised CCN process, the

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637

ICN/CCN approach can be used to migrate the on-

going service from the source data centre to the new

destination data centre. The ICN/CCN approach can

also be used to migrate a VM running on the source

data centre to the new destination data centre. The

latter can be accomplished by enabling the

destination data centre to request an on-going VM

from the source data centre, by using one or more

Interest messages.

5 CONCLUSIONS AND FUTURE

WORK

By analyzing and comparing different technologies,

this paper argued and verified that the ICN/CCN

technology is a promising candidate that can

efficiently be used for the support of service and VM

migration in the virtualized LTE system.

In order to further validate this statement, the use

of the ICN/CCN technology for the support of

service and VM migration in the virtualized LTE

system will be prototyped and evaluated within the

context of the EU FP7 project (EU FP7 MCN,

2013).

ACKNOWLEDGEMENTS

This work is accomplished in the context of the EU

FP7 Mobile Cloud Networking (MCN) project.

Therefore, we would like to acknowledge the

European Commission, since the MCN project is an

EC funded Integrated Project under the 7th RTD

Framework Programme, FP7-ICT-2011-8-grant

agreement number 318109.

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