UTRA (Universal Terrestrial Radio Access) as a 3rd generation system, with the enhancements provided by High Speed Packet Access (HSPA), for both downlink and uplink, will remain highly competitive for several years. Nevertheless, the industry that has developed the 3GPP technologies, launched a project in Dec. 2004 called Long Term Evolution (LTE) to study requirements for a new air interface called Evolved UTRA (E-UTRA).
Note: The terms LTE and E-UTRA are synonymous, however the radio specifications talk rather about E-UTRA.
The results of this study i.e. the E-UTRA/LTE requirements were documented in Rel-7 3GPP TR 25.913:
Significantly increased peak data rates e.g. 100 Mbps in downlink/50 Mbps in uplink
Increased bitrates at the edge of cells assuming current site locations
Improved spectrum efficiency e.g. 2-4 x Rel-6
Reduced latency
Scaleable bandwidth for a greater flexibility in frequency allocations
Reduced capital and operational expenditure including backhaul
Acceptable system and terminal complexity, cost and power consumption
Support for inter-working with existing 3G systems and non-3GPP specified systems
Efficient support of the various types of services, especially from the PS domain (e.g. Voice over IP, Presence)
Optimized for low mobile speed but supporting high mobile speed (up to 500 km/h).
Following the definition of the E-UTRA/LTE requirements, the same Rel-7 study produced a 3GPP TR 25.912 "Feasibility study for evolved Universal Terrestrial Radio Access (UTRA) and Universal Terrestrial Radio Access Network (UTRAN)" to describe how the radio part of the system could be designed. Corresponding normative E-UTRA/LTE work followed then from Sep. 2006 until March 2009 in Rel-8 specifications.
In parallel to the radio architecture evolution a Study on 3GPP System Architecture Evolution (SAE) was carried out with the objective to develop a framework for an evolution or migration of the 3GPP system to a higher-data-rate, lower-latency, packet-optimized system that supports multiple Radio Access Technologies. The focus of this work was on the PS domain with the assumption that voice services are supported in this domain. This study resulted in Rel-8 3GPP TR 23.882 and was followed by corresponding normative Rel-8 work.
Although the term "Evolved UTRA" implies a gradual enhancement of the existing 3rd generation UMTS system, it became finally a different radio access technology:
while UMTS started with a focus on circuit-switched data that was then more and more enhanced via shared channels and HSPA into the direction of a packet switched system, LTE is a pure packet-switched system
while UMTS was using CDMA, LTE is using OFDMA (Orthogonal Frequency Division Multiple Access) in downlink (evolved NodeB (eNodeB) => User Equipment (UE)) and SC-FDMA (Single Carrier- Frequency Division Multiple Access) in uplink (UE => eNodeB) Note 1: SC-FDMA has lower peak-to-average power ratios (PAPR) than OFDMA which was preferred for an easier UE power amplifier design/a higher efficiency (increased coverage/lower power consumption) Note 2: SC-FDMA is also called DFT-S-OFDM which indicates that it can be understood as a precoding (by Discrete Fourier transform) plus the same OFDMA that is used in downlink
while UMTS (at least FDD and 3,84Mcps TDD) used a channel bandwidth of 5MHz, LTE allows 6 different channel bandwidths: 1,4/3/5/10/15/20MHz
while UMTS has an RNC (radio network controler) between NodeB and core network, the functionalities of this network entity are split between eNodeB and core network in LTE => no RNC in LTE => flat/simpler radio architecture
Nevertheless, UMTS/UTRA as well as LTE/E-UTRA use both a 10ms radio frame, both have FDD and TDD modes and LTE/E-UTRA supports full interoperability with UMTS/UTRA and GSM/GERAN/EDGE.
LTE-Advanced
Rel-10/Rel-11/Rel-12
Additional spectrum proposed for IMT systems by WRC-07 in 2007 (in 450 MHz band, in UHF band (698-960 MHz), in 2.3-2.4 GHz band, in C-band(3400-4200 MHz)) as well as the ITU-R request for the development of an IMT-Advanced radio interface (Circular Letter of March 2008) triggered developments of the 4th generation of mobile communication systems.
According to ITU-R M.1645 (overall objectives for beyond IMT-2000) and M.2134 (IMT-Advanced requirements) the key features for IMT-Advanced were summarized as follows:
a high degree of commonality of functionality worldwide while retaining the flexibility to support a wide range of services and applications in a cost efficient manner
compatibility of services within IMT and with fixed networks
capability of interworking with other radio access systems
high-quality mobile services
user equipment suitable for worldwide use
user-friendly applications, services and equipment
worldwide roaming capability
enhanced peak data rates to support advanced services and applications (100 Mbit/s for high and 1 Gbit/s for low mobility were established as targets for research)
3GPP was at that time in the phase to complete its Rel-8 LTE WI and it started an early Rel-9 study item (FS_RAN_LTEA, RP-091360) in March 2008 to define in 3GPP TR 36.913 the requirements for a mobile communication system called LTE-Advanced under the following conditions:
LTE-Advanced shall be an evolution of Release 8 LTE system
All requirements of LTE of 3GPP TR 25.913 are also valid for LTE-Advanced
LTE-Advanced shall meet or exceed IMT-Advanced requirements within the ITU-R time plan
Note: The terms LTE-Advanced and Advanced E-UTRA are synonymous.
3GPP TR 36.913 on "Requirements for further advancements for Evolved Universal Terrestrial Radio Access (E-UTRA) (LTE-Advanced)" was approved at RAN #40 in June 2008 (still under Rel-8).
The following figure from ITU-R M.1645 illustrates the differences between IMT-2000 (3rd generation) and IMT-Advanced (4th generation):
In addition, the same study started in March 2008 a 3GPP TR 36.912 on Feasibility study for "Further Advancements for E-UTRA (LTE-Advanced)" in order to analyse certain areas in which LTE could be enhanced, e.g.
Support of wider bandwidth: aggregation of multiple component carriers with up to 20MHz bandwidth,
Spatial multiplexing: DL up to 8 layers, UL up to 4 layers,
Coordinated multiple point transmission and reception: to improve the coverage of high data rates, the cell-edge throughput and/or to increase system throughput
Relaying functionality: to improve e.g. the coverage of high data rates, group mobility, temporary network deployment, the cell-edge throughput and/or to provide coverage in new areas
to fulfill and exceed the IMT-Advanced requirements.
This TR 36.912 was approved in Sep.2009 (RAN #45) as Rel-9 TR and further updated at RAN #46 and RAN #47 (March 2010) where the SI was completed.
In Release 10 individual work items were started introducing enhancements of LTE that were discussed in the Rel-9 study item for LTE-Advanced:
Carrier Aggregation for LTE (LTE_CA): Dec.09 - June 11; RP-100661
UL multiple antenna transmission for LTE (LTE_UL_MIMO): Dec.09 - June 11; RP-100959
Enhanced Downlink Multiple Antenna Transmission for LTE (LTE_eDL_MIMO): Dec.09 - March 11; RP-100196
Coordinated Multi-Point Operation for LTE: only a study was started in Rel-10 which completed in Rel-11 and resulted in normative work in Rel-11 with further enhancements in Rel-13 and Rel-15
Relays for LTE (LTE_Relay): Dec.09 - June 11; RP-110911
Latency reduction: WI was stopped as it was not possible to complete this in Rel-10 (it came back a L2 latency reduction in Rel-14 and was completed there)
Further enhancements to MBMS for LTE (MBMS_LTE_enh): June 10 - March 11; RP-101244
LTE Self Optimizing Networks (SON) enhancements (SONenh_LTE): March 10 - June 11; RP-101004
Minimization of drive tests for E-UTRAN and UTRAN (MDT_UMTSLTE): Dec.09 - June 11; RP-100360
Note: There is no separate Radio Access Technology "LTE-Advanced". All enhancements of LTE in Rel-10 and beyond are integrated into the LTE specifications as they were developed in Rel-8 and Rel-9.
3GPP contributed to IMT-Advanced project of ITU-R via an early preliminary input from RAN #41 in Sep.2008 (RP-080763) and a final submission including self-evaluation results from RAN #45 in Sep.2009 (RP-090939).
Note: RP-090939 includes RP-090745 which provides the characteristics of LTE-Advanced in a condensed template format.
In Jan. 2012, the Radiocommunication Assembly approved ITU-R Recommendation M.2012 "Detailed specifications of the terrestrial radio interfaces of International Mobile Telecommunications-Advanced (IMT-Advanced)" (RP-120005) and confirmed LTE-Advanced as IMT-Advanced radio interface technology.
Note 1: There is only one other IMT-Advanced radio interface technology called "WirelessMAN-Advanced" developed by IEEE).
Note 2: About every 2 years, ITU-R M.2012 is updated by 3GPP with latest enhancements.
LTE-Advanced Pro
Rel-13 and above
All enhancements of LTE of Rel-13 and beyond (if not related to 5G) are running under the trademark "LTE Advanced Pro", for example:
Rel-13 (Sep.14-Dec.15, ASN.1 freeze: March 16):
Narrowband Internet of Things (IOT)
Further LTE Physical Layer Enhancements for MTC
Dual Connectivity enhancements for LTE Extension of Dual Connectivity in E-UTRAN
Licensed-Assisted Access (LAA) using LTE
Elevation Beamforming/Full-Dimension (FD) MIMO for LTE
Indoor Positioning enhancements for UTRA and LTE
Further Enhancements of Minimization of Drive Tests for E-UTRAN
Enhanced LTE Device to Device Proximity Services
Multicarrier Load Distribution of UEs in LTE
Support of single-cell point-to-multipoint transmission in LTE
Enhanced Signalling for Inter-eNB Coordinated Multi-Point (CoMP) for LTE
RAN enhancements for extended DRX in LTE
LTE-WLAN Radio Level Integration and Interworking Enhancement, LTE-WLAN RAN Level Integration supporting legacy WLAN
RAN aspects of Application specific Congestion control for Data Communication
Base Station (BS) RF requirements for Active Antenna System (AAS), SON for AAS-based deployments
Dedicated Core Networks
RAN Aspects of RAN Sharing Enhancements for LTE
Radiated requirements for the verification of multi-antenna reception perf. of UEs
UE core requirements for uplink 64 QAM
LTE DL 4 Rx antenna ports
Rel-14 (Dec.15-March 17, ASN.1 freeze: June 17):
Enhancements of NB-IoT
Further enhanced MTC for LTE
Flexible eNB-ID and Cell-ID in E-UTRAN
Enhanced LAA for LTE
Support for V2V services based on LTE sidelink, LTE-based V2X Services
Enhancements on Full-Dimension (FD) MIMO for LTE
Downlink Multiuser Superposition Transmission for LTE
SRS (sounding reference signal) switching between LTE component carriers
Further Indoor Positioning Enhancements for UTRA and LTE
Uplink Capacity Enhancements for LTE
eMBMS enhancements for LTE
L2 latency reduction techniques for LTE
Further mobility enhancements in LTE
Voice and Video Enhancement for LTE
Enhanced LTE-WLAN Aggregation (LWA), Enhanced LTE WLAN Radio Level Integration with IPsec Tunnel (eLWIP)
Enhancements of Dedicated Core (DECOR) Networks for UMTS and LTE
LTE Measurement Gap Enhancement
Requirements for a new UE category with single receiver based on Cat.1 for LTE
Performance enhancements for high speed scenario in LTE
4 receiver (RX) antenna ports with Carrier Aggregation for LTE downlink (DL)
Multi-Band Base Station testing with three or more bands
Radiated perf. requirements for the verification of multi-antenna reception of UEs
Note: For Rel-15 and onwards, LTE related specifications even carry the 5G logo as they were part of the SRIT IMT-2020 input (see 5G page for further explanation).
Rel-15 (March 17-June 18, ASN.1 freeze: Sep.18):
Further NB-IoT enhancements
Even further enhanced MTC for LTE
Enhancements to LTE operation in unlicensed spectrum
V2X phase 2 based on LTE
Further enhancements to Coordinated Multi-Point (CoMP) Operation for LTE
UE Positioning Accuracy Enhancements for LTE
Enhancements for high capacity stationary wireless link and intro of DL 1024 QAM
Bluetooth/WLAN measurement collection in LTE Minimization of Drive Tests
Quality of Experience Measurement Collection for streaming services in E-UTRAN
UL data compression in LTE
Increased number of E-UTRAN data bearers
Further video enhancements for LTE
Shortened TTI and processing time for LTE, Ultra Reliable Low Latency Communication for LTE
LTE connectivity to 5G-CN
Enhanced LTE Support for Aerial Vehicles
Enhancing LTE CA Utilization
UE requirements for network-based CRS interference mitigation for LTE
UE requirements for LTE DL 8Rx antenna ports
Enhancements of BS RF and EMC requirements for Active Antenna System
Rel-16 (June 18 - June 20, ASN.1 freeze: June 20):
Additional enhancements for NB-IoT
Additional MTC enhancements for LTE
DL MIMO efficiency enhancements for LTE
Even further mobility enhancement in E-UTRAN
Support for NavIC Navigation Satellite System for LTE
Further performance enhancement for LTE in high speed scenario
LTE-based 5G terrestrial broadcast
And a number of work items driven by LTE & NR:
5G V2X with NR sidelink
Multi-RAT Dual-Connectivity and Carrier Aggregation enhancements (LTE, NR)
Optimisations on UE radio capability signalling – NR/E-UTRA Aspects
eNB(s) Architecture Evolution for E-UTRAN and NG-RAN
Introduction of capability set(s) to multi-standard radio specifications
Rel-17 (June 20 - March 22, ASN.1 freeze planned for June 22):
Additional enhancements for NB-IoT and LTE-MTC
NB-IoT/eMTC support for Non-Terrestrial Networks
Additional LTE bands for UE categories M1/M2/NB1/NB2
Further LTE Carrier Aggregation combinations
New bands and bandwidth allocation for 5G terrestrial broadcast
And a number of work items driven by LTE & NR:
Further Multi-RAT Dual-Connectivity enhancements
Support for Multi-SIM devices for LTE/NR
Enhanced eNB(s) architecture evolution for E-UTRAN and NG-RAN
Enhancement of data collection for SON (Self-Organising Networks)/MDT (Minimization of Drive Tests) in NR standalone and MR-DC (Multi-Radio Dual Connectivity)
Further RRM enhancement for NR and Multi-RAT-Dual Connectivity
NR and Multi-RAT-Dual Connectivity measurement gap enhancements
User Plane Integrity Protection support for EPC connected architectures
High power UE (power class 2) for EN-DC
Band combinations for concurrent operation of NR/LTE Uu bands/band combinations and one NR/LTE V2X PC5 band
LTE/NR spectrum sharing in LTE band 40/NR band n40
Simultaneous Rx/Tx band combinations for NR Carrier Aggregation/Dual Connectivity, NR Supplemental Uplink and LTE/NR Dual Connectivity
Further band combinations for Dual Connectivity LTE/NR
Rel-18 (March 22 - December 23, ASN.1 freeze planned for March 24):
IoT (Internet of Things) NTN (non-terrestrial network) enhancements
Introduction of LTE TDD band in 1 670 to 1 675 MHz
And a number of work items driven by LTE & NR:
In-Device Co-existence (IDC) enhancements for NR and MR-DC
Artificial Intelligence (AI)/Machine Learning (ML) for NG-RAN
Further enhancement of data collection for SON (Self-Organizing Networks)/MDT (Minimization of Drive Tests) in NR standalone and MR-DC (Multi-Radio Dual Connectivity)
BS/UE EMC enhancements for NR and LTE
Further RF requirements enhancement for NR and EN-DC in frequency range 1 (FR1)
Support of intra-band non-collocated EN-DC/NR-CA deployment
Further enhancements on NR and MR-DC measurement gaps and measurements without gaps
3GPP TS 21.201 provides a list of all specifications related to the 4th generation (including core network EPC (Evolved Packet Core) and system aspects). The 4G network architecture is described in 3GPP TS 23.003
We use cookies or similar technologies to collect data about your use of this website and to improve your experience when using it. To find out how to disable our cookies, please visit our Privacy Policy.