Über die Autorin bzw. den Autor

KAMRAN ETEMAD received his PhD in electrical engineering from the University of Maryland. Most recently, he has been with Nexius Inc. and Wireless Facilities Inc. as the Vice President of Advanced Technology. His research interests include current and emerging telecommunication technologies and standards development as well as tools and process design for network planning, traffic engineering, and propagation analysis of mobile and fixed wireless systems. He has developed and taught numerous courses and seminars in both academia and industry, and published many papers in wireless communication and networking. Dr. Etemad is also a lecturer at the University of Maryland.

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An insightful guide to CDMA2000^® for implementing successful next-generation mobile and wireless networks

CDMA2000^® Evolution: System Concepts and Design Principles is the comprehensive resource you need to understand concepts, techniques, and protocols used in the design of a widely deployed family of next-generation mobile wireless standards: the CDMA2000^® standard, including the CDMA2000® 1x (IS2000), and the 1xEV-DO (or IS856/HRPD) systems.

All systems are examined in depth, from the physical channelization to coding, spreading, and modulation schemes. The author leads you through:

• The key enabling 3G technology concepts, such as link adaptation, Hybrid ARQ, adaptive scheduling, and diversity schemes
• The Release 0/A of the IS2000 system and the key technical enhancements made to recent releases of the standard
• The IS2000 Releases C and D, including forward and reverse high-speed packet data channel operation
• 1xEV-DO/IS856, including the new enhancements and features in EV-DO Rev. A
• MAC/LAC layer protocols and signaling procedures
• Network architecture, QoS, radio network performance, and dimensioning
• Comparisons with other 2.5G/3G systems

From simpler legacy systems to the more advanced revisions made to these standards, the emphasis is on conceptual understanding of key techniques and protocols, and their evolution. Carefully balancing theory and practical insights, CDMA2000^® Evolution: System Concepts and Design Principles provides engineers, technical managers, and students in telecommunications with a solid foundation of the new concepts, protocols, and methodologies used for the design of next-generation CDMA networks and systems.

Aus dem Klappentext

An insightful guide to CDMA2000^® for implementing successful next-generation mobile and wireless networks

CDMA2000^® Evolution: System Concepts and Design Principles is the comprehensive resource you need to understand concepts, techniques, and protocols used in the design of a widely deployed family of next-generation mobile wireless standards: the CDMA2000^® standard, including the CDMA2000® 1x (IS2000), and the 1xEV-DO (or IS856/HRPD) systems.

All systems are examined in depth, from the physical channelization to coding, spreading, and modulation schemes. The author leads you through:

• The key enabling 3G technology concepts, such as link adaptation, Hybrid ARQ, adaptive scheduling, and diversity schemes
• The Release 0/A of the IS2000 system and the key technical enhancements made to recent releases of the standard
• The IS2000 Releases C and D, including forward and reverse high-speed packet data channel operation
• 1xEV-DO/IS856, including the new enhancements and features in EV-DO Rev. A
• MAC/LAC layer protocols and signaling procedures
• Network architecture, QoS, radio network performance, and dimensioning
• Comparisons with other 2.5G/3G systems

From simpler legacy systems to the more advanced revisions made to these standards, the emphasis is on conceptual understanding of key techniques and protocols, and their evolution. Carefully balancing theory and practical insights, CDMA2000^® Evolution: System Concepts and Design Principles provides engineers, technical managers, and students in telecommunications with a solid foundation of the new concepts, protocols, and methodologies used for the design of next-generation CDMA networks and systems.

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CDMA2000 Evolution

John Wiley & Sons

Chapter One

1.1 INTRODUCTION

The ongoing growth in demand for high-speed packet data services and multimedia applications over mobile wireless networks has set new system requirements and objectives for the next generation of air interface protocols and network architectures.

Although the channelization, signaling, and access protocols of second-generation (2G) cellular systems were designed to efficiently support symmetric circuit switched data and voice traffic, most of the new data applications are IP based with highly asymmetric and packet-switch traffic. This asymmetric and bursty nature of multimedia packet data traffic along with the variability of data rates and packet sizes and complexity of quality of service (QoS) management makes conventional voice-oriented channelization and access protocols of 2G systems inefficient.

The third generations of radio access technologies, commonly known as 3G systems, are expected to use new physical and logical channelization schemes with enhanced media and link access control protocols. Also, to maximize the spectrum efficiency, the physical layer designs must utilize advanced coding, link adaptation, and diversity schemes as well as power and interference control mechanisms.

In the late 1990s, these observations and requirements motivated major efforts and studies in the International Telecommunication Union (ITU) and other regional standardization groups to define and harmonize a common set of specifications for new International Mobile Telecommunications standards referred to as IMT2000 systems. In Europe the IMT2000 is also referred to as Universal Mobile Telecommunication Services (UMTS).

ITU activities on IMT2000 are comprised of international standardization, including frequency spectrum and technical specifications for radio and network components, tariffs and billing, technical assistance, and studies on regulatory and policy aspects.

In this chapter we briefly present the overview of 3G evolution paths while we defer a more detailed description of technologies to later chapters.

The IMT2000 has defined a globally acceptable spectrum for the deployment of 3G systems, including uniband spectrum to support the time division duplex (TDD) mode as well as paired-band spectrum to allow the frequency division duplex (FDD) mode. In the FDD mode the system uses different frequency bands for the mobile station transmissions in the "uplink" and base station transmissions in the "downlink." In the TDD mode the uplink and downlink transmissions are on the same frequency channel but they are separated by time slots. Although most 3G deployments are expected to be in paired frequencies or in FDD mode, the TDD mode may also be used in unlicensed bands and when an FDD allocation is not feasible.

In early 1998, to expedite the process of IMT2000/3G standardization and the global acceptance of proposed radio transmission technologies (RTTs), a concept of a "Partnership Project" was proposed by the European Telecommunications Standards Institute (ETSI). This proposal initiated two Third-Generation Partnership Projects (3GPP and 3GPP2) with two different, but related, areas of focus. Each of the 3GPP and 3GPP2 projects involves a number of regional standardization bodies as organizational partners as shown in Figure 1.1.

For 3GPP the original scope was to produce globally applicable and acceptable technical specifications for a Third-Generation Mobile System based on evolved Global System for Mobile communication (GSM) core networks. Initially, the objective was to focus on the Universal Terrestrial Radio Access (UTRA) technologies with both FDD and TDD modes. This scope was subsequently amended to include the maintenance and development of Technical Specifications for GSM and its evolution to General Packet Radio Service (GPRS) and Enhanced Data rates for GSM Evolution (EDGE).

Similarly, the scope of the 3GPP2 work was to harmonize different variations of cdma2000(r) in a single family of standards that is based on the evolution of cdmaONE air interface. This scope was also expanded to include the development of a data-optimized air interface called the high-rate packet data (HRPD) system. In the development of cdma2000 systems the core network specifications are based on an evolved ANSI-41 and IP network; however, the specifications also include the necessary capabilities for operation with an evolved GSM-MAP-based core network. For more information on 3GPP and 3GPP2 the reader is referred to.

As a result of harmonization efforts in 3GPP and 3GPP2, the following three major technologies have been identified and included in the IMT2000 family of standards:

IMT2000 FDD Mode; Direct Spread: WCDMA (wideband code division multiple access) is one of the key radio access technologies adopted as an IMT2000 standard for global deployment in the FDD spectrum. WCDMA is based on direct spread spectrum technology in 5-MHz radio channels supporting mobile multimedia applications with up to 2 Mbps for local area access or 384 kbps for wide area access. The WCDMA standardization process has evolved from its first release in 1999 to an updated version (Release 5) in 2002, which contains major revisions and additions to the previous releases including a new high-speed data packet access (HSDPA) mode to allow high speed and low latency access for packet data applications. IMT2000 FDD Mode; Multicarrier: The multicarrier CDMA, commonly referred to as the cdma2000 standards family, is the other FDD component of IMT2000 systems. The main member of the cdma2000 family of standards is the IS2000 air interface with the 1X and 3X components, corresponding to one and three 1.25-MHz carrier systems, respectively. The IS2000 is designed to provide a backward-compatible migration path for 2G-CDMA/IS95A(B) networks. The cdma2000 family also includes the IS856 standard, which was subsequently added as an optional and complementary radio access technology that is optimized HRPD access. IMT2000 TDD Mode (UTRA-TDD/TD-CDMA): The TDD mode of IMT2000 standards involves a TDD variation of WCDMA, which uses a combination of time- and code division multiple access referred to as TDCDMA. The TDD mode also has an optional spreading rate of 1.28 Mcps, which is based on synchronous code division multiple access called TDSCDMA.

Figure 1.2 shows the timeline for the evolution of various 2G technologies toward IMT2000/3G systems, with emphasis on the commonly used FDD technologies.

Most GSM networks have evolved to include GPRS services and in some cases have been further enhanced to EDGE system for higher-speed packet data services. GPRS reuses GSM radio channels and frame structure and provides higher data rates to allow multislot traffic channels. The EDGE enhances GPRS spectral efficiency by using higher-order modulation with link adaptation but still maintaining GSM radio channels and frame structure.

Most GSM operators are planning or have begun deploying IMT2000/UMTS-based networks using WCDMA technology. Many IS136/TDMA-based networks have also joined the GSM group and have decided to migrate to WCDMA. In Japan the PDC-based networks were among the first to deploy the WCDMA...