Why do we need 5G?
- Mobile data traffic is rising rapidly, mostly due to video streaming.
- With multiple devices, each user has a growing number of connections.
- Internet of Things will require networks that must handle billions more devices.
- With a growing number of mobiles and increased data traffic both mobiles and networks need to increase energy efficiency.
- Network operators are under pressure to reduce operational expenditure, as users get used to flat rate tariffs and don't wish to pay more.
- The mobile communication technology can enable new use cases (e.g. for ultra-low latency or high reliability cases) and new applications for the industry, opening up new revenue streams also for operators.
So 5G should deliver significantly increased operational performance (e.g. increased spectral efficiency, higher data rates, low latency), as well as superior user experience (near to fixed network but offering full mobility and coverage). 5G needs to cater for massive deployment of Internet of Things, while still offering acceptable levels of energy consumption, equipment cost and network deployment and operation cost. It needs to support a wide variety of applications and services.
Comparison of key capabilities of IMT-Advanced (4th generation) with IMT-2020 (5th generation) according to ITU-R M.2083:
Who is interested in using 5G?
5G offers network operators the potential to offer new services to new categories of users.
What are the main usage scenarios of 5G?
ITU-R has defined the following main usage scenarios for IMT for 2020 and beyond in their Recommendation ITU-R M.2083:
- Enhanced Mobile Broadband (eMBB) to deal with hugely increased data rates, high user density and very high traffic capacity for hotspot scenarios as well as seamless coverage and high mobility scenarios with still improved used data rates
- Massive Machine-type Communications (mMTC) for the IoT, requiring low power consumption and low data rates for very large numbers of connected devices
- Ultra-reliable and Low Latency Communications (URLLC) to cater for safety-critical and mission critical applications
which requires different key capabilities according to ITU-R M.2083:
How is the 5G standard developed?
ITU-R has set up a project called IMT-2020 to define the next generation of mobile communication networks for 2020 and beyond with the following time plan:
At TSG #67 in March 2015, 3GPP formulated with SP-150149 a 3GPP timeline on how to contribute to this 5th generation of mobile networks.
In connection with RAN #69 in Sep. 2015, 3GPP held a workshop in Phoenix, USA in order to inform 3GPP about the ITU-R IMT-2020 plans and to share the visions and priorities of the involved companies regarding the next generation radio technology/ies.
The chairman's summary (RWS-150073) formulated 3 next steps:
- preparation of channel modeling work for high frequencies
- a study to develop scenarios and requirementsfor next generation radio technology
- a study for RAN WGs to evaluate technology solutions for next generation radio technology
At RAN #69 in Sep.15, 3GPP started a Rel-14 study item (FS_6GHz_CH_model, RP-160210) "Study on channel model for frequency spectrum above 6 GHz". This study completed at RAN #72 in June 2016 with the 3GPP TR 38.900.
Note 1: LTE-Advanced was so far aggregating spectrum of up to 100MHz and was so far operating in bands below 6GHz. This study looks at the frequency range 6-100GHz and bandwidths below 2GHz.
Note 2: The whole contents of this TR was later transferred into 3GPP TR 38.901 "Study on channel model for frequencies from 0.5 to 100 GHz" covering the whole frequency range.
At RAN #70 in Dec. 2015, 3GPP started already a Rel-14 study item (FS_NG_SReq, RP-160811) "Study on Scenarios and Requirements for Next Generation Access Technologies" with the goal to identify the typical deployment scenarios (associated with attributes such as carrier frequency, inter-site distance, user density, maximum mobility speed, etc.) and to develop specific requirements for them for the next generation access technologies (taking into account what is required for IMT-2020).
This study completed at RAN #74 in Dec. 2016 with the 3GPP TR 38.913 which describes scenarios, key performance requirements as well as requirements for architecture, migration, supplemental services, operation and testing.
In March 2016, ITU-R invited for candidate radio interface technologies for IMT-2020 in a Circular Letter. The overall objectives of IMT-2020 were set via ITU-R M.2083 and the requirements were provided in ITU-R M.2410 like e.g.:
The minimum requirements:
- for peak data rate:: Downlink: 20 Gbit/s, Uplink: 10 Gbit/s
- for peak spectral efficiencies: Downlink: 30 bit/s/Hz, Uplink: 15 bit/s/Hz
- user plane latency (single user, small packets): 4 ms for eMBB, 1 ms for URLLC
- control plane latency (idle => active): 10-20ms
- maximum aggregated system bandwidth: at least 100 MHz, up to 1GHz in higher frequency bands (above 6GHz)
- mobility: up to 500km/h in rural eMBB
At RAN #71 in March 2016, 3GPP started a Rel-14 study item (FS_NR_newRAT, RP-170379) "Study on New Radio (NR) Access Technology" with the goal to identify and develop the technology components to meet the broad range of use cases (including enhanced mobile broadband, massive MTC, critical MTC) and the additional requirements defined in 3GPP TR 38.913. This study completed at RAN #75 in March 17 with the Rel-14 3GPP TR 38.912 which is a collection of features for the new radio access technologies together with the studies of their feasibility and their capabilities.
Note: Included in this study item were also some RAN Working Group (WG) specific 3GPP internal TRs: 38.802 (RAN1), 38.804 (RAN4), 38.801 (RAN3), 38.803 (RAN4).
At RAN #75 in March 17, 3GPP started a Rel-15 work item (NR_newRAT, RP-181726) on "New Radio Access Technology". Over time this WI got split into 3 phases addressing different network operator demands:
- "early Rel-15 drop": focus on architecture option 3, also called non-standalone NR (NSA NR) which could be considered as the first migration step of adding NR base stations (called gNB) to an LTE-Advanced system of LTE base stations (eNB) and an evolved packet core network (EPC) i.e. in this option no 5G core network (5GC) is involved; functional freeze: Dec.17, ASN.1 freeze in March 18
- "regular Rel-15 freeze": focus on the standalone NR architecture option 2 which would be a network of NR base stations (gNB) connected to the 5G core network (5GC) without any LTE involvement; functional freeze: June 18; ASN.1 freeze in Sep.18;
Note: Originally all other architecture options were supposed to be completed in this regular freeze phase as well. However, due to the extremely challenging time plan apart from option 2 only architecture option 5 (an LTE base station can be connected to a 5GC) was completed in this phase as well.
- "late Rel-15 drop": architecture option 4 (this would be like adding an LTE base station to an SA NR network where the control plane is handled via the NR base station) and architecture option 7 (this would be like adding an LTE base station to an SA NR network where the control plane is handled via the LTE base station) plus NR-NR Dual Connectivity; functional freeze: Dec.18; ASN.1 freeze in March 19;
Note 1: Illustrations of the different architecture options can be found in 3GPP TR 38.801 (with the caveat that the terminology was not yet stable during this study phase).
Note 2: Rel-15 is distinguishing 2 frequency ranges: FR1: 450 MHz – 6000 MHz and FR2: 24250 MHz – 52600 MHz; while LTE is operating only in FR1, NR can operate in FR1 and FR2; that's why FR1 is considered for NSA NR and FR2 is considered for SA NR.
As LTE-Advanced can fulfill parts of the IMT-2020 requirements for certain use cases the 3GPP input (called "5G") to IMT-2020 will have 2 submissions:
- SRIT (set of radio interface technologies): component RIT NR + component RIT E-UTRA/LTE (incl. standalone LTE, NB-IoT, eMTC, and LTE-NR Dual Connectivity)
- RIT (radio interface technology) NR
Note: The terms RIT and SRIT are discussed and explained in RP-171584.
When will the 5G standard be ready?
Splitting Rel-15 into multiple drops turned out to be very challenging, e.g.
- NSA NR had still non-backward compatible Change Requests in Sep.18
- inserting ASN.1 into an already frozen specification requires very high quality change requests which is difficult under high time pressure
- WGs that require stable pre-work from other WGs (like RAN4 for RF/RRM and RAN5 for Testing) are working on instable grounds and struggle even more to stay in the time plan
Nevertheless, 3GPP contributed in time to the IMT-2020 schedule shown below:
- in Jan. 2018 via PCG40_11 with initial characteristics of the NR RIT and NR+LTE SRIT
- in Sep./Oct.2018 via PCG41_08 with the characteristics of the NR RIT and NR+LTE SRIT, the preliminary self-evaluation and link budget results and the compliance templates
Note: The characteristics templates give a good overview about the considered technology.
A final 3GPP input is then planned for mid of 2019 and this will also include further Rel-16 enhancements.
The Rel-16 ASN.1 freeze is planned for March 2020. Like with GERAN, UMTS and LTE in the past, 5G will be further evolved in the future to address the industry and customer demands.
Where to find the corresponding 5G specifications?
Radio related specifications addressing only NR: 38 series specifications.
Radio related specifications addressing only LTE: 36 series specifications.
Radio related specifications addressing aspects affecting both LTE and NR: 37 series specifications.
Service requirements for next generation new services and markets: 3GPP TS 22.261.
System Architecture for the 5G system (stage 2): 3GPP TS 23.501.
Procedures for the 5G System (stage 2): 3GPP TS 23.502.
NR; NR and NG-RAN Overall Description (stage 2): 3GPP TS 38.300.
NR; Multi-connectivity; Overall description (stage 2): 3GPP TS 37.340.
NG-RAN; Architecture description: 3GPP TS 38.401.
ETSI's 5G Building Blocks
ETSI has a number of component technologies which will be integrated into future 5G systems: Network Functions Virtualization (NFV), Multi-access Edge Computing (MEC), Millimetre Wave Transmission (mWT) and Next Generation Protocols (NGP).