It’s not here yet, but 5G is closer than you think

Author : Sarah Yost, mmWave Product Manager at National Instruments

28 September 2017

Credit: metrue/Shutterstock
Credit: metrue/Shutterstock

The race to define 5G may be ending, but the process to design and deploy 5G technology is just beginning.

This piece originally appeared in the October 2017 issue of Electronic Product Design & Test; to view the digital edition, click here – and to register to receive your own printed copy, click here.

5G is the centrepiece of exciting new wireless technologies and applications. While recent announcements from Mobile World Congress indicate that 5G is already here – it’s not, quite… but we’re getting very close. This article from National Instruments discusses why, for wireless communications, it’s all about 5G…

The wireless communications community has had a busy year. From progress on the standardisation process and essential updates communicated by regulatory bodies, to gaining understanding of the channel for newly-proposed millimetre wave (mmWave) frequencies and technologies under development – that will turn 5G into a commercial reality – anticipation for 5G is at an all-time high. So, what do all the accomplishments from the past year mean? And when will 5G finally be here?

5G frequencies: a combination of mm Wave and sub-6 GHz

Figure 1. Targeted 5G applications include enhanced mobile broadband and machine-to-machine communication
Figure 1. Targeted 5G applications include enhanced mobile broadband and machine-to-machine communication

There is much still to be defined when it comes to 5G, but one thing is certain: sub-6 GHz spectrum remains important, while mmWave frequencies will be used to supplement sub-6 GHz technology.

Figure 1 shows the wide range of requirements expected of 5G, from ultra-reliable, high-bandwidth communication for enhanced mobile broadband (eMBB) applications, to the low-bandwidth, machine-to-machine (M2M) type communications we expect to see in IoT (Internet of Things) applications. It is difficult, if not impossible, for one band of spectrum to meet all these needs, but combining two bands provides complementary coverage. Sub-6 GHz spectrum offers better propagation and backwards compatibility for narrowband applications, while the contiguous bandwidth at mmWave frequencies enables the key eMBB applications that 5G promises.

The timeline

The International Telecommunications Union (ITU) has defined two phases of research, as shown in Figure 2: Phase 1 for sub-40 GHz and Phase 2 for sub-100 GHz. Phase 1 is scheduled to end in June 2018, to correspond with the 3GPP’s Long Term Evolution (LTE) release 15; Phase 2 is slated to end in December 2019, to correspond with LTE release 16. Figure 2 shows both the ITU and 3GPP timelines as of autumn 2016.The ITU’s proposed dates and the frequencies that will be used, however, are anything but certain. At the March 2017 3GPP RAN plenary meeting (#75), a Way Forward (WF) was presented with an accelerated schedule for the release of 5G New Radio (NR), as seen in Figure 3.

Figure 2. ITU and 3GPP timelines for 5G | Image source:
Figure 2. ITU and 3GPP timelines for 5G | Image source:

NTT DOCOMO presented its recommendation for which frequency bands to use during the last RAN4 meeting (#82) in a Way Forward (WF). Table 1 summarises the frequency ranges and corresponding telecom operators.

28 GHz and Verizon

The work at 28 GHz has dominated the news on sub-40 GHz research over the past year, but it is not the only frequency under consideration; the FCC and Verizon have been driving the work at 28 GHz. To allocate additional mmWave bands for flexible use and future-proposed rulemaking, the FCC approved the Spectrum Frontiers Proposal in July 2016. The 28 GHz band is one of the three bands available today for flexible use in the United States [1]. Figure 4 presents a graph of the bands. Based on the WF at the RAN4 meeting, global carriers (including European operators, Orange, British Telecom and Telecom Italia) have established significant alignment around 24 to 28 GHz. This may seem surprising, based on previous conclusions that 28 GHz is an unsuitable band for Europe given its frequency incumbents; but the lower frequencies in that band have potential. As expected, those same European operators are requesting spectrum at 32 GHz.

Verizon secured a licence for the 28 GHz band from XO Communications last year, and has been vocal about its desire to use this frequency for its initial deployment. Despite not having a fully standardised version of the technology to roll out for this testing, Verizon is making a bet that the hardware they deploy will be able to run whichever specification is eventually released through a future software update [2]. Other US carriers have agreed to use the 28 GHz band, and both AT&T and T-Mobile indicated that they will conduct more research on 28 GHz-based technologies and partner with equipment providers for additional field trials.

Figure 3. Accelerated 3GPP NR Release Schedule (as of March 2017)
Figure 3. Accelerated 3GPP NR Release Schedule (as of March 2017)

In 2015, Verizon established the 5G Technical Forum (5GTF) with Cisco, Ericsson, Intel, LG, Nokia, Qualcomm and Samsung. The working group’s main goal was to develop a wireless alternative to Fibre to The Home (FTTH) using mmWave spectrum, also known as Fixed Wireless Access (FWA). The 5GTF draws largely from the LTE standard and adds concepts now being researched and proposed for 5G in 3GPP.

The 5GTF extends the subcarrier spacing by a multiple of 5 (75 kHz subcarriers versus 15 kHz, yielding 100 MHz bandwidth per component carrier), and it reduces the subframe spacing by an inverse proportion to maintain timing consistency with LTE. The 5GTF has also added control signals and expanded the physical layer to include digital beam-forming and precoding.

At the 2017 IEEE Wireless Communications and Networking Conference (WCNC) in San Francisco, National Instruments demonstrated a real-time working prototype of the 5GTF. While it was not the first prototype of the specification, it was notable for several reasons – one of which being that it was the first public demonstration of the technology in action.

Verizon is aware that it will push out mmWave technology pre-standardisation. The question looming over V5G is whether or not it will comply with 3GPP 5G standards, hence the risk of deploying mmWave technology before the standards are defined. If Verizon’s gamble pays off, Verizon will have a significant head start in the race to 5G. If not, it will need to replace a lot of outdated hardware.

Table 1. Proposed New Radio (NR) Spectrum Way Forward from RAN4 Meeting
Table 1. Proposed New Radio (NR) Spectrum Way Forward from RAN4 Meeting

New Radio (NR)

NR is intended to cover all applications and all frequency bands, including the three main application key performance indicators for 5G put forth by the ITU: enhanced mobile broadband (eMBB), Ultra Reliable Low Latency Communications (URLLC), and Massive Machine Type Communications (MMTC). This means that the physical layer needs to be flexible enough to generate significantly higher data throughput, while allowing for hundreds of times more devices to connect to the network for Narrow Band IoT (NB-IoT). The PHY also needs to be sufficiently reliable and with low enough latency to be used in self-driving cars. This is no easy task, and the standards that are being proposed for NR are significantly more complex than V5G. Certain aspects, such as adding beam management, are similar between the two; but NR will incorporate both slow and fast beam management. NR will also leverage LTE as much as possible (although it uses different sample and subcarrier rates).

Despite the buzz around NR, and a desire to finalise the standard earlier than initially planned, not much data has been published about the performance of the specification. The limited trials at 28 GHz have focused more on channel sounding than demonstrating the feasibility of the NR specification. National Instruments (NI) has developed a New Radio prototyping system that can run a multi-user MIMO link. This system uses the NI mmWave Transceiver System (MTS) and flexible physical layer IP written in LabVIEW.

A 2018 finish line for the race to 5G 

Figure 4. mmWave Bands allocated by the FCC
Figure 4. mmWave Bands allocated by the FCC

By early 2018, we will likely have an answer to the question: ‘What is 5G?’. Based on the accelerated schedule presented at the March 2017 3GPP RAN plenary meeting (#75), the physical layer and MAC layer for NR will be settled by the end of 2017. Frequency selection does not have a strict deadline, but operators are pushing technology forward to get 28 GHz hardware deployed in 2017 field trials. By the second quarter of 2018, South Korea will have demonstrated its 5G technology preview. The full standardisation process will not be complete yet, but a clearer picture of 5G will begin to emerge. The race to define 5G may be ending, but the process to design and deploy 5G technology is just beginning.


[1] Use of Spectrum Bands Above 24 GHz for Mobile Radio Services, GN Docket No. 14-177, Notice of Proposed Rulemaking, 15 FCC Record 138A1 (rel. Oct. 23, 2015)


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