UMTS Protocols and Protocol Testing

Electromagnetic waves were first discovered as a communication medium at the end of the 19th century. The first systems offering mobile telephone service (car phone) were introduced in the late 1940s in the USA and in the early 1950s in Europe. Those early “Single Cell Systems” were severely constrained by restricted mobility, low capacity, limited service and poor speech quality. The equipment was heavy, bulky, expensive and susceptible to interference. Because of those limitations, less than one million subscribers were registered worldwide by the early 1980s.

1.1.1 First Generation (1G) – Analog Cellular

The introduction of cellular systems in the late 1970s/early 1980s represented a quantum leap in mobile communication (especially in capacity and mobility). Semiconductor technology and microprocessors made smaller, lighter weight and more sophisticated mobile systems a practical reality for many more users. These First Generation cellular systems still transmit only analog voice information. The most prominent 1G systems are AMPS (Advanced Mobile Phone System), NMT (Nordic Mobile Telephone) and TACS (Total Access Communication System). With the 1G introduction, the mobile market showed annual growth rates of 30-50%, rising to nearly 20 million subscribers by 1990.

1.1.2 Second Generation (2G) – Multiple Digital Systems

The development of 2G cellular systems was driven by the need to improve transmission quality, system capacity and coverage. Further advances in semiconductor technology and microwave devices brought digital transmission to mobile communications. Speech transmission still dominates the airways, but the demands for fax, short message and data transmissions are growing rapidly. Supplementary services such as fraud prevention and encrypting of user data have become standard features that are comparable to those in fixed networks. 2G cellular systems include GSM (Global System for Mobile Communication), D-AMPS (Digital AMPS), CDMA (Code Division Multiple Access) and PDC (Personal Digital Communication).

Today, multiple 1G and 2G standards are used in worldwide mobile communications. Different standards serve different applications with different levels of mobility, capability and service area (Paging Systems, Cordless Telephone, Wireless Local Loop, Private Mobile Radio, Cellular Systems and Mobile Satellite Systems). Many standards are used only in one country or region, and most are incompatible. GSM is the most successful family of cellular standards (GSM900, GSM-R, GSM1800 and GSM1900 and GSM400), supporting some 250 million of the world’s 450 million cellular subscribers with International Roaming in approximately 140 countries and 400 networks.

1.1.3 2G to 3G: GSM Evolution

Phase 1 of the standardization of GSM900 was completed by ETSI in 1990 and included all necessary definitions for GSM network operations. Several Tele- and Bearer-Services have been defined (including data transmission up to 9.6 kbit/s), but only some very basic supplementary services were offered. As a result, GSM standards were enhanced in Phase 2 (1995) to incorporate a large variety of supplementary services that were comparable to digital fixed network ISDN standards. In 1996 ETSI decided to further enhance GSM in annual Phase 2+ releases that incorporate 3G capabilities.

GSM Phase 2+ releases have introduced important 3G features such as Intelligent Network services with CAMEL, enhanced speech codecs EFR and AMR, high data rate services and new transmission principles with HSCSD, GPRS and EDGE. UMTS is a 3G GSM successor standard that is downward compatible with GSM, using the GSM Phase 2+ enhanced Core Network.

1.2 Third Generation (3G): IMT-2000

The main characteristics of 3G systems, known collectively as IMT-2000,are a single family of compatible standards that are:

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IMT-2000 is a set of requirements defined by the ITU. IMT stands for International Mobile Telecommunication, “2000” represents both the scheduled year for initial trial systems and the frequency range of 2000 MHz (WARC’92: 1885 - 2025 MHz & 2110 - 2200 MHz). All 3G standards have been developed by “regional” Standard Development Organizations (SDO). In total, proposals for 17 different IMT-2000 standards were submitted by regional SDOs to ITU in 1998 - 11 proposals for terrestrial systems and 6 for Mobile Satellite Systems (MSS). Evaluation of the proposals was completed at the end of 1998, and negotiations to build consensus among differing views were completed in mid 1999. All 17 proposals have been accepted by ITU as IMT-2000 standards. The specification for the Radio Transmission Technology (RTT) was released at the end of 1999.

The most important IMT-2000 proposals are the UMTS (W-CDMA) as the successor to GSM, cdma2000 as the IS-95 successor and TD-SCDMA (UWC-136/EDGE) as TDMA-based enhancements to D-AMPS/GSM – all of which are leading previous standards toward the ultimate goal of IMT 2000.

UMTS (Universal Mobile Telecommunication System), also referred to as W-CDMA, is one of the most significant advances in the evolution of telecommunications into 3rd Generation Mobile Networks. UMTS allows many more applications to be introduced to a worldwide base of users and provides a vital link between today’s multiple GSM systems and the ultimate single worldwide standard for all mobile telecommunications (IMT-2000). The new network also addresses the growing demand of mobile and Internet applications for new capacity in the overcrowded mobile communications sky. UMTS increases transmission speed to 2 Mbits/s per mobile user and establishes a global roaming standard.

UMTS is being developed by 3GPP (Third Generation Partnership Project), a joint venture of several Standards Development Organizations - ETSI (Europe), ARIB/TTC (Japan), ANSI T1 (USA), TTA (South Korea) and CWTS (China). To reach global acceptance, 3GPP is introducing UMTS in Phases and Annual Releases. The first release (UMTS Rel. ‘99), introduced in December of 1999, defines enhancements and transitions for existing GSM networks. For the second Phase (UMTS Rel. ´00), similar transitions are being proposed as enhancements for IS95 (with cdma2000) and TDMA (with TD-CDMA and EDGE)

The most significant change in Rel. ‘99 is the new UMTS Terrestrial Radio Access (UTRA), a W-CDMA radio interface for land based communications. UTRA supports Time Division Duplex (TDD) and Frequency Division Duplex (FDD). The TDD mode is optimized for public Micro & Pico cells and unlicensed cordless applications. The FDD mode is optimized for wide area coverage; i.e. public Macro & Micro cells. Both modes offer flexible and dynamic data rates up to 2 Mbit/s. Another newly defined UTRA mode – Multi Carrier (MC) – is expected to establish compatibility between UMTS and cdma2000.

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2 UMTS network architecture

2.1 Principles

UMTS (Rel. '99) incorporates enhanced GSM Phase 2+ Core Networks with GPRS (General Packet Radio Services) and CAMEL (Customized Applications for Mobile network Enhanced Logic). This enables network operators to enjoy the improved cost efficiency of UMTS while protecting their 2G investments and reducing the risks of implementation.

In UMTS release 1 (Rel. '99), a new radio access network UTRAN (UMTS Terrestrial Radio Access Network) is introduced. UTRAN, the UMTS RAN, is connected via the Iu-Interface (Iu-PS for PS data / Iu-CS for CS data) to the GSM Phase 2+ CN.

"GSM-only" Mobile Stations (MS) will be connected to the network via the Um GSM radio interface. UMTS/GSM Dual-Mode User Equipment (UE) will be connected to the network via UMTS radio interface Uu at very high data rates (up to almost 2 Mbit/s). Outside the UMTS service area, UMTS/GSM UE will be connected to the network at reduced data rates via the Um GSM air interface.

Maximum data rates are 115 kbit/s for CS data by HSCSD (High Speed Circuit Switched Data), 171 kbit/s for PS data by GPRS and 553 kbit/s by EDGE (Enhanced Data Rates for the GSM Evolution). Handover between UMTS and GSM is supported, and handover between UMTS and other 3G systems (e.g. MC-CDMA) will be supported in order to achieve true worldwide access.

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2.2 The UMTS Network Architecture

The Public Land Mobile Network (PLMN) described in UMTS Rel. ´99 incorporates three major categories of network elements:

2.2.1 Network Elements from GSM Phase 1/2

The GSM Phase 1/2 PLMN consists of three subsystems: the Base Station Subsystem (BSS), the Network Switching Subsystem (NSS) and the Operation Subsystem (OSS). The BSSconsists of the functional units: Base Station Controller (BSC), Base Transceiver Station (BTS) and Transcoding & RateAdaptation Unit (TRAU). TheNSS consists of the functional units: Mobile Services switching Center (MSC), Visitor Location Register (VLR), Home Location Register (HLR), Equipment Identity Register (EIR) and the Authentication Center (AC). The MSC provides functions such as switching, signaling, Paging, and Inter-MSC Handover. TheOSS consists of Operation & Maintenance Centers (OMC), which are used for remote and centralized Operation, Administration and Maintenance tasks.

2.2.2 Network Elements from GSM Phase 2+GPRS (General Packet Radio Services)

The most important evolutionary step of GSM towards UMTS is GPRS. GPRS introduces Packet Switching (PS) into the GSM Core Network and allows direct access to Packet Data Networks (PDN). This enables high data rate PS transmission well beyond the 64 kbit/s limit of ISDN through the GSM CN, a necessity for UMTS data transmission rates of up to 2 Mbit/s. GPRS prepares and optimizes the CN for high data rate PS transmission, as does UMTS with UTRAN over the RAN. Thus, GPRS is a prerequisite for the UMTS introduction.

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Two functional units extend the GSM NSS architecture for GPRS PS services: the Gateway GPRS Support Node (GGSN) and the Serving GPRS Support Node (SGSN).

The GGSN has functions comparable to a GMSC. The SGSN resides at the same hierarchical level as a VMSC/VLR and therefore performs comparable functions such as routing and mobility management.

CAMEL (Customized Applications for Mobile network Enhanced Logic)

CAMEL enables worldwide access to operator specific Intelligent Network (IN) applications such as Prepaid, Call Screening, and Supervision. CAMEL is the primary GSM Phase 2+ enhancement for the introduction of the UMTS Virtual Home Environment (VHE) concept. VHE is a platform for flexible service definition (collection of Service Creation Tools) that enables the operator to modify or enhance existing services and/or to define new services. Furthermore, VHE enables worldwide access to these operator-specific services in every GSM and UMTS PLMN and introduces Location Based Services (by interaction with GSM/UMTS Mobility Management).

A CAMEL Service Environment (CSE) and a new CCS7 protocol, the CAMEL Application Part (CAP) are required on the CN to introduce CAMEL.

2.2.3 Network Elements from UMTS Phase 1

As mentioned above, UMTS differs from GSM Phase 2+ mostly in the new principles for air interface transmission (W-CDMA instead of TDMA/FDMA). Therefore, a new radio access network called UTRAN must be introduced with UMTS. Only minor modifications, such as allocation of the transcoding function (TC) for speech compression to the CN, are needed in the Core Network to accommodate the change. The TC function is used together with an Interworking Function (IWF) for protocol conversion between the A and the Iu-CS interfaces.

UTRAN (UMTS Terrestrial Radio Access Network)

The UMTS standard can be seen as an extension of existing networks. Two new network elements are introduced in UTRAN, Radio Network Controller (RNC) and Node B. UTRAN is subdivided into individual Radio Network Systems (RNS), where each RNS is controlled by a Radio Network Controller (RNC). The RNC is connected to a set of Node B elements, each of which can serve one or several cells.

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Existing network elements, such as MSC, SGSN and HLR, can be extended to adopt the UMTS requirements, but RNC, Node B and the handsets must be completely new designs. RNC will become the replacement for BSC, and Node B fulfills nearly the same functionality as BTS. GSM and GPRS networks will be extended and new services will be integrated into an overall network that contains both existing interfaces such as A, Gb, Abis and new interfaces that include Iu, Iub and Iur

UMTS defines four new open interfaces: