3GPP is consortium with seven regional telecommunication associations as primary members ("organizational partners") and a variety of other organizations as associate members ("market representation partners"). The 3GPP organizes its work into three different streams: Radio Access Networks, Services and Systems Aspects, and Core Network and Terminals.
The project was established in December 1998 with the goal of developing a specification for a 3G mobile phone system based on the 2G GSM system, within the scope of the International Telecommunication Union's International Mobile Telecommunications-2000. It should not be confused with 3rd Generation Partnership Project 2 (3GPP2), which developed a competing 3G system, CDMA2000.
The 3rd Generation Partnership Project initiative eventually arose from a strategic initiative between Nortel Networks and AT&T Wireless. In 1998 AT&T Wireless was operating an IS-136 (TDMA) wireless network in the United States. In 1997 Nortel Networks' Wireless R&D center in Richardson, Texas, the wireless division of Bell Northern Research had developed a vision for "an all Internet Protocol (IP)" wireless network that went under the internal name "Cell Web". As the concept progressed, Nortel launched the industry vision as "Wireless Internet". AT&T Wireless, poised to evolve its network in the United States, took a strong interest in Wireless Internet and its promise of Internet Protocol (with Nortel Networks as the potential supplier). Within 12 months or so, AT&T launched a global initiative that they named "3GIP", a third generation wireless standard that was "natively" Internet Protocol based. Initially, principal participants included British Telecom, France Telecom, Telecom Italia, and Nortel Networks, but were eventually joined by NTT DoCoMo, BellSouth, Telenor, Lucent, Ericsson, Motorola, Nokia, and others. A 3GIP standards forum was instituted and standards began to be developed. The forum progressed into the 2000 time frame, up until AT&T Wireless and British Telecom formed a strategic "partnership project" to facilitate "global roaming" between U.S. and European markets. With this business arrangement, GSM, the prevailing European standard was adopted as the basis of AT&T Wireless' network evolution for North America. Very specifically, this included the deployment of GSM data capabilities, i.e. GPRS, EDGE, and its evolution to UMTS.
The seven 3GPP Organizational Partners are from Asia, Europe and North America. Their aim is to determine the general policy and strategy of 3GPP and perform the following tasks:
Together with the Market Representation Partners (MRPs) perform the following tasks:
The Organizational Partners are:
|Association of Radio Industries and Businesses (ARIB)||Japan||ARIB|
|Alliance for Telecommunications Industry Solutions (ATIS)||USA||ATIS|
|China Communications Standards Association (CCSA)||China||CCSA|
|European Telecommunications Standards Institute (ETSI)||Europe||ETSI|
|Telecommunications Standards Development Society (TSDSI)||India||TSDSI|
|Telecommunications Technology Association (TTA)||South Korea||TTA|
|Telecommunication Technology Committee (TTC)||Japan||TTC|
The 3GPP Organizational Partners can invite a Market Representation Partner to take part in 3GPP, which:
As of June 2017, the Market Representation Partners are:
|5G Automotive Association||5gaa|
|5G Infrastructure Association||5GIA|
|Mobility Development Group (former CDMA Development Group)||MobilityDG|
|Cellular Operators Association of India (COAI)||coai|
|Global Certification Forum (GCF)||GCF|
|Global Mobile Suppliers Association (GSA)||gsacom|
|GSM Association (GSMA)||gsmworld|
|Next Generation Mobile Networks (NGMN)||ngmn|
|Public Safety Communication Europe (PSCE) Forum||PSCE|
|Small Cell Forum (formerly Femto Forum)||smallcellforum|
|TD SCDMA Industry Alliance||tdscdma|
|TETRA and Critical Communications Association (TCCA)||tcca|
|Wireless Broadband Alliance||WB Alliance|
3GPP standards are structured as Releases. Discussion of 3GPP thus frequently refers to the functionality in one release or another.
|Phase 1||1992||GSM Features|
|Phase 2||1995||GSM Features, EFR Codec,|
|Release 96||1997 Q1||GSM Features, 14.4 kbit/s User Data Rate,|
|Release 97||1998 Q1||GSM Features, GPRS|
|Release 98||1999 Q1||GSM Features, AMR codec, EDGE, GPRS for PCS1900|
|Release 99||2000 Q1||Specified the first UMTS 3G networks, incorporating a CDMA air interface|
|Release 4||2001 Q2||Originally called the Release 2000 - added features including an all-IP Core Network|
|Release 5||2002 Q1||Introduced IMS and HSDPA|
|Release 6||2004 Q4||Integrated operation with Wireless LAN networks and adds HSUPA, MBMS, enhancements to IMS such as Push to Talk over Cellular (PoC), GAN|
|Release 7||2007 Q4||Focuses on decreasing latency, improvements to QoS and real-time applications such as VoIP. This specification also focus on HSPA+ (High Speed Packet Access Evolution), SIM high-speed protocol and contactless front-end interface (Near Field Communication enabling operators to deliver contactless services like Mobile Payments), EDGE Evolution.|
|Release 8||2008 Q4||First LTE release. All-IP Network (SAE). New OFDMA, FDE and MIMO based radio interface, not backwards compatible with previous CDMA interfaces. Dual-Cell HSDPA. UMTS HNB.|
|Release 9||2009 Q4||SAES Enhancements, WiMAX and LTE/UMTS Interoperability. Dual-Cell HSDPA with MIMO, Dual-Cell HSUPA. LTE HeNB.|
|Release 10||2011 Q1||LTE Advanced fulfilling IMT Advanced 4G requirements. Backwards compatible with release 8 (LTE). Multi-Cell HSDPA (4 carriers).|
|Release 11||2012 Q3||Advanced IP Interconnection of Services. Service layer interconnection between national operators/carriers as well as third party application providers. Heterogeneous networks (HetNet) improvements, Coordinated Multi-Point operation (CoMP). In-device Co-existence (IDC).|
|Release 12||2015 Q1||Enhanced Small Cells (higher order modulation, dual connectivity, cell discovery, self configuration), Carrier aggregation (2 uplink carriers, 3 downlink carriers, FDD/TDD carrier aggregation), MIMO (3D channel modeling, elevation beamforming, massive MIMO), New and Enhanced Services (cost and range of MTC, D2D communication, eMBMS enhancements)|
|Release 13||2016 Q1||LTE in unlicensed, LTE enhancements for Machine-Type Communication. Elevation Beamforming / Full-Dimension MIMO, Indoor positioning.LTE-Advanced Pro.|
|Release 14||2017 Q2||Energy Efficiency, Location Services (LCS), Mission Critical Data over LTE, Mission Critical Video over LTE, Flexible Mobile Service Steering (FMSS), Multimedia Broadcast Supplement for Public Warning System (MBSP), enhancement for TV service, massive Internet of Things, Cell Broadcast Service (CBS)|
|Release 15||2018 Q2||First NR ("New Radio") release. Support for 5G Vehicle-to-x service, IP Multimedia Core Network Subsystem (IMS), Future Railway Mobile Communication System|
Each release incorporates hundreds of individual standards documents, each of which may have been through many revisions. Current 3GPP standards incorporate the latest revision of the GSM standards.
The documents are made available without charge on 3GPP's web site. The standards cover not only the radio part ("Air Interface") and Core Network, but also billing information and speech coding down to source code level. Cryptographic aspects (such as authentication, confidentiality) are also specified. 3GPP2 offers similar information about its system.
The 3GPP specification work is done in Technical Specification Groups (TSGs) and Working Groups (WGs).
There are three Technical Specifications Groups, each of which consists of multiple WGs:
|RAN WG1||RAN1||Radio Layer 1 specification||List of specs|
|RAN WG2||RAN2||Radio Layer 2 and Radio Layer 3 RR specification||List of specs|
|RAN WG3||RAN3||Iub Iur and Iu specification - UTRAN O&M requirements||List of specs|
|RAN WG4||RAN4||Radio performance and protocol aspects (system) - RF parameters and BS conformance||List of specs|
|RAN WG5||RAN5||Mobile terminal conformance testing||List of specs|
|RAN WG6||RAN6||GERAN radio and protocol||List of specs|
|SA WG1||SA1||Services||List of specs|
|SA WG2||SA2||Architecture||List of specs|
|SA WG3||SA3||Security||List of specs|
|SA WG4||SA4||Codec||List of specs|
|SA WG5||SA5||Telecom Management||List of specs|
|SA WG6||SA6||Mission-critical applications||List of specs|
|CT WG1||CT1||MM/CC/SM (lu)||List of specs|
|CT WG3||CT3||Interworking with external networks||List of specs|
|CT WG4||CT4||MAP/GTP / BCH/SS||List of specs|
|CT WG5||CT5||OSA (Now transferred to OMA)|
|CT WG6||CT6||Smart Card Application Aspects||List of specs|
The closure of GERAN was announced in January 2016. The specification work on legacy GSM/EDGE system was transferred to a new RAN WG, RAN6.
The 3GPP structure also includes a Project Coordination Group, which is the highest decision-making body. Its missions include the management of overall timeframe and work progress.
3GPP standardization work is contribution-driven. Companies ("individual members") participate through their membership to a 3GPP Organizational Partner. As of April 2011, 3GPP is composed of more than 370 individual members.
Specification work is done at WG and at TSG level:
Test specifications are sometimes defined as stage 4, as they follow stage 3.
Specifications are grouped into releases. A release consists of a set of internally consistent set of features and specifications.
Timeframes are defined for each release by specifying freezing dates. Once a release is frozen, only essential corrections are allowed (i.e. addition and modifications of functions are forbidden). Freezing dates are defined for each stage.
The 3GPP specifications are transposed into deliverables by the Organizational Partners.
3GPP systems are deployed across much of the established GSM market. They are primarily Release 6 systems, but as of 2010, growing interest in HSPA+ and LTE is driving adoption of Release 7 and its successors. Since 2005, 3GPP systems were seeing deployment in the same markets as 3GPP2 systems (for example, North America). With LTE the official successor to 3GPP2's CDMA systems, 3GPP-based systems will eventually become the single global mobile standard.