Evolved Packet Core for LTE: Market Forecast & Competitive Analysis

Evolved Packet Core for LTE: Market Forecast & Competitive Analysis published by Heavy Reading in November, 2009. This report consists of 69 Pages and the price starts from US $ 3995.

Introduction

Abstract

With the success of 3G data and with operators starting to plan and deploy Long Term Evolution (LTE), mobile networks are going through a period of deep, lasting, change. The transition to LTE/System Architecture Evolution (SAE) involves a fundamental shift to a "flat" all-IP system architecture that impacts every part of the network, with the Evolved Packet Core (EPC) at its center. SAE specifies an all-IP network architecture designed to support end-to-end packet services. It comprises two tightly integrated components: the Evolved UMTS Terrestrial Radio Access Network (E-UTRAN) - a.k.a. LTE RAN - and EPC.

EPC provides session, mobility, and quality-of-service (QoS) management in LTE networks and is the conduit through which operators connect users to applications on the Internet, on corporate networks, and in the operator' s own service delivery environment. Requirements for the EPC to support guaranteed delivery of critical, low-latency services, such as voice, alongside high-throughput, best-effort Internet services on a single infrastructure place demanding new requirements on the packet core equipment, which must scale in multiple dimensions to meet the needs of next-generation mobile broadband networks.

One of these dimensions is the network "intelligence" inherent to EPC that allows operators to differentiate treatment of services and applications according to technical and commercial policies. This makes EPC is critical to enabling operators to monetize and profit from the vast capital investment and operational expense of mobile broadband networks. It is also increasingly clear that, while EPC is primarily thought of in relation to LTE, the technology and architecture is aligned with, and fundamentally suited to supporting a common packet core network for 2G, 3G, and LTE radio access. This concept of a common packet core underlines the deeply strategic nature of EPC product development and network deployment models.

For operators, the common core concept implies a multi-year strategic view of not just LTE/SAE introduction, but also of existing voice and packet core networks, the underlying packet transport domain, and interaction with the policy control and service delivery layer. Because operators' long-term target architecture definitions depend on product capability and technology suppliers' ability to meet roadmap commitments, the impact on equipment vendors is similarly far-reaching.

Established mobile packet core vendors are naturally in prime position to lead the market to EPC, but the all-IP nature of the technology and the potentially disruptive nature of the architecture open the opportunity up to, and increase the responsibility on, vendors from across the carrier networking ecosystem. In this sense EPC is also of direct relevance to suppliers in switching and routing, backhaul, policy, IMS, security, VOIP, OSS/BSS, and radio access suppliers.

Evolved Packet Core for LTE: Market Forecast & Competitive Analysis provides a crucial roadmap that charts how network operators will migrate to LTE/SAE, and how that migration will shape their core network technology choices. It identifies and analyzes the key technology and deployment issues that mobile operators must deal with regarding the transition from 2G and 3G to LTE, and assesses technology platforms and choices for EPC network elements in the context of evolving control- and bearer-plane requirements.

This report offers a complete competitive analysis of EPC technology suppliers and evaluates deployment models now being considered for EPC. It also includes Heavy Reading' s first-ever five-year forecast for the mobile packet core sector, including a breakout of MPC technology spending by technology type through 2014.

Table of Contents

LIST OF FIGURES

I. INTRODUCTION & KEY FINDINGS

• 1.1 Key Findings
• 1.2 Report Scope & Structure

II EPC ARCHITECTURE & TECHNOLOGY

• 2.1 Network Architecture
• 2.2 EPC Technology Features
  • Evolved Packet Service is All-IP
  • Flat Architecture
  • Separate Control & Bearer Planes
  • QoS & Policy Changing & Control
  • Non 3GPP Access
  • Other Enhancements to EPS & EPC

III TECHNOLOGY PLATFORMS FOR EPC

• 3.1 Platform Requirements
  • Control Plane Scaleability - Transaction Rate is Key
  • Bearer Plane Scaleability - Traffic Analysis & Managements is Key
• 3.2 Platform Choices: Edge Routers, ATCA & Purpose-Built
  • Edge Router Platforms
  • ATCA Platforms
  • Purpose-built Platforms
• 3.3 Vendor Strategies for EPC Platforms
• 3.4 Vendor Platform Analysis - Control Plane
  • MME Product Comparison
  • Combining SGSN & MME Nodes
• 3.5 Vendor Platform Analysis - Bearer Plane
  • SAE-GW Product Comparison
  • Combining SAE-GW & GGSN Nodes

IV. DEPLOYMENT MODELS FOR EPC

• 4.1 EPC Deployment Options
• 4.2 From EPC Overlay to Common Packet Core
• 4.3 Centralized vs. Distributed Deployment
• 4.4 Software Upgrades to EPC
• 4.5 Integration With Transport

V. MOBILE PACKET CORE VENDOR POSITIONING

• 5.1 Vendor Market Share
  • Share of the Combined 3GPP/GPP2 Packet Core Market
  • Share of 3GPP Market
• 5.2 Vendor Momentum in Mobile Packet Core
• 5.3 Acquisitions, Consolidation & Partnerships
  • Cisco - Starent Acquisition
• 5.4 Vendors in the Orbit of EPC
• 5.5 Best of Breed vs. End-to-End
• 5.6 Design, Integration, & Network Management Services

VI. MOBILE PACKET CORE MARKET SIZE & FORECAST

• 6.1 Market Size & Growth Forecast
  • Forecast Methodology
  • Price per Subscriber
• 6.2 Packet Core Market by Technology

VII. EPC VENDOR PROFILES

• 7.1 Alcatel-Lucent
• 7.2 Cisco Systems
• 7.3 Ericsson
• 7.4 Hitachi
• 7.5 Huawei
• 7.6 Juniper Networks
• 7.7 Motorola
• 7.8 NEC
• 7.9 Nokia Siemens Networks
• 7.10 Starent
• 7.11 WiChorus
• 7.12 ZTE

APPENDIX A: ABOUT THE AUTHOR

APPENDIX B: LEGAL DISCLAIMER

Related Reports