Month: July 2020
Non-coherent Massive MIMO for High-Mobility Communications
By Ana García Armada, PhD, Professor at Universidad Carlos III de Madrid
Introduction:
While driving on a highway in Europe (as a passenger), I tried my smartphone’s 4G-LTE connection and the best I could get was 30 Mbps downlink, 10 Mbps uplink, with latency around 50 msec. This is not bad for many of the applications we use today, but it is clearly insufficient for many low latency/low jitter mobile applications, such as autonomous driving or high-quality video while on the move.
At higher speeds, passengers of ultra-fast trains may enjoy the travel while working. Their 4G-LTE connections are often good enough to read or send emails and browse the internet. But would a train passenger be able to have a video conference call with good quality? Would we ever be able to experience virtual reality or augmented reality in such a high mobility environment?
How to achieve intelligent transport systems enabling vehicles to communicate with each other has been the subject of several papers and reports as per Reference [1]. Many telecommunications professionals are looking to 5G for a solution, but it is not at all certain that the IMT 2020 performance requirements specified in ITU-R M.2410 for low latency with high speed mobility will be met anytime soon (by either 3GPP Release 16 or IMT 2020 compliant specifications).
Editor’s Note: In ITU-R M.2410, the minimum requirements for IMT 2020 (“5G”) user plane latency are: 4 ms for eMBB (enhanced mobile broadband) and 1 ms for URLLC (ultra high reliability, ultra low latency communications).
IMT 2020 is expected to be approved by ITU-R SG D after their November 23-24,2020 meeting, which is one week after the ITU-R WP 5D approval at their November 17-19, 2020 meeting.
There are three different “5G Radios” being progressed as IMT 2020 RIT/SRIT submissions: 3GPP, DECT/ETSI, and Nufront. The TSDSI’s (India) submission adds Low Mobility Large Cell (LMLC) to 3GPP’s “5G NR.”
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The fundamental reason why we do not experience high data rates using 4G-LTE lies in the signal format. That did not change much with 3GPP’s “5G NR,” which is the leading candidate IMT 2020 Radio Interface Technology (RIT). Please refer to Editor’s Note above.
In coherent detection, a local carrier mixes with the received radio frequency (RF) signal to generate a product term. As a result, the received RF signal can be frequency translated and demodulated. When using coherent detection, we need to estimate the channel (frequency band). The amount of overhead strongly depends on the channel variations. That is, the faster we are moving, the higher the overhead. Therefore, the only way to obtain higher data rates in these circumstances is to increase the allocated bandwidth (e.g. with carrier aggregation [2]) for a particular connection, which is obviously a non-scalable solution.
Coherent Communications, CSI, and OFDM Explained:
A coherent receiver creates a replica of the transmitted carrier, as perfectly synchronized (using the same frequency and the same phase) as possible. Combining coherent detection with the received signal, the baseband data is recovered with additive noise being the only impairment.
However, the propagation channel usually introduces some additional negative effects that distorts the amplitude and phase of the received signal (when compared to the transmitted signal). Hence, the need to estimate the channel characteristics and remove the total distortion. In wireless communications, channel state information (CSI) refers to known channel properties of a communication link, i.e. the channel characteristics. CSI needs to be estimated at the receiver and is usually quantized and sent back to the transmitter.
Orthogonal frequency-division multiplexing (OFDM) is a method of digital signal modulation in which a single data stream is split across several separate narrowband channels at different frequencies to reduce interference and crosstalk. Modern communications systems using OFDM carefully design reference signals to be able to estimate the CSI as accurately as possible. That requires pilot signals in the composite Physical layer frame (in addition to the digital information being transmitted) in order to estimate the CSI. The frequency of those reference signals and the corresponding amount of overhead depends on the characteristics of the channel that we would like to estimate from some (hopefully) reduced number of samples.
Wireless communications were not always based on coherent detection. At the time of the initial amplitude modulation (AM) and frequency modulation (FM), the receivers obtained an estimate of the transmitted data by detecting the amplitude or frequency variations of the received signal without creating a local replica of the carrier. But their performance was very limited. Indeed, coherent receivers were a break-through to achieve high quality communications.
Other Methods of Signal Detection:
More recently, there are two popular ways of non-coherently detecting the transmitted data correctly at the receiver.
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One way is to perform energy or frequency detection in a similar way to the initial AM and FM receivers.
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In differential encoding, we encode the information in the phase shifts (or phase differences) of the transmitted carrier. Then, the absolute phase is not important, but just its transitions from one symbol to the other. The differential receivers are much simpler than the coherent ones, but their performance is worse since noise is increased in the detection process.
Communications systems that prioritize simple and inexpensive receivers, such as Bluetooth [3], use non-coherent receivers. Also, differential encoding is an added feature in some standards, such as Digital Audio Broadcasting (DAB). The latter was one of the first, if not the first standard, to use OFDM in wireless communications. It increases the robustness to mitigate phase distortions, caused by the propagation channel for mobile, portable or fixed receivers.
However, the vast majority of contemporary wireless communications systems use coherent detection. That is true for 4G-LTE and “5G NR.”
Combining non-coherent communications with massive MIMO:
Massive MIMO (multiple-input, multiple-output) groups together antennas at the transmitter and receiver to provide better throughput and better spectrum efficiency. When massive MIMO is used, obtaining and sharing CSI threatened to become a bottleneck, because of the large number of channels that need to be estimated because there are a very large number of antennas.
A Universidad Carlos III de Madrid research group started looking at a combination of massive MIMO with non-coherent receivers as a possible solution for good quality (user experience) high speed mobile communications. It is an interesting combination. The improvement of performance brought by the excess of antennas may counteract the fundamental performance loss of non-coherent schemes (usually a 3 dB signal-to-noise ratio loss).
Indeed, our research showed that if we take into account the overhead caused by CSI estimation in coherent schemes, we have shown several cases in which non-coherent massive MIMO performs better than its coherent counterpart. There are even cases where coherent schemes do not work at all, at least with the overheads considered by 4G-LTE and 5G (IMT 2020) standards. Yet non-coherent detection usually works well under those conditions. These latter cases are most prevalent in high-mobility environments.
Editor’s Note: In ITU-R M.2410, high speed vehicular communications (120 km/hr to 500 km/hr) is mainly envisioned for high speed trains. No “dead zones” are permitted as the “minimum” mobility interruption time is 0 ms!
When to use non-coherent massive MIMO?
Clearly in those situations where coherent schemes work well with a reasonable pilot signal overhead, we do not need to search for alternatives. However, there are other scenarios of interest where non-coherent schemes may substitute or complement the coherent ones. These are cases when the propagation channel is very frequency selective and/or very time-varying. In these situations, estimating the CSI is very costly in terms of resources that need to be used as pilots for the estimation. Alternatives that do not require channel estimation are often more efficient.
An interesting combination of non-coherent and coherent data streams is presented in reference [5], where the non-coherent stream is used at the same time to transmit data and to estimate the CSI for the coherent stream. This is an example of how coherent and non-coherent approaches are complementary and the best combination can be chosen depending on the scenario. Such a hybrid scheme is depicted in the figure below.
Figure 1. Suitability of coherent (C), non-coherent (NC) and hybrid schemes (from reference [5])
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What about Millimeter Waves and Beam Steering?
The advantage of millimeter waves (very high frequencies) is the spectrum availability and high speeds. The disadvantages are short distances and line of sight communications required.
Compensating for the overhead by adding more bandwidth, may be a viable solution. However, the high propagation loss that characterizes these millimeter wave high frequency bands creates the need for highly directive antennas. Such antennas would need to create narrow beams and then steer them towards the user’s position. This is easy when the user equipment is fixed or slowly moving, but doing it in a high speed environment is a real challenge.
Note that the beam searching and tracking systems that are proposed in today’s wireless communications standards, won’t work in high speed mobile communications when the User Endpoint (UE) has moved to the coverage of another base station at the time the steering beams are aligned! There is certainly a lot of research to be done here.
In summary, the combination of non-coherent techniques with massive MIMO does not present any additional problems when they are carried out in millimeter wave frequencies. For example, reference [6] shows how a non-coherent scheme can be combined with beamforming, provided the beamforming is performed by a beam tracking procedure. However, the problem of how to achieve fast beam alignment remains to be solved.
Concluding Remarks:
Non-coherent massive MIMO makes sense in wireless communications systems that need to have very low complexity or that need to work in scenarios with high mobility. Its advantage is that it makes possible communications in places or circumstances where the classical coherent communications fail. However, this scheme will not perform as well as coherent schemes under normal conditions.
Most probably, non-coherent massive MIMO will be used in the future as a complement to well-understood and (usually) well-performing coherent systems. This will happen when there are clear market opportunities for high mobility, high speed, low latency use cases and applications.
References:
[1] ITU report: “Setting the scene for 5G: opportunities and challenges”, 2018, https://www.itu.int/en/ITU-D/Documents/ITU_5G_REPORT-2018.pdf
[2] F. Kaltenberger et al., “Broadband wireless channel measurements for high speed trains,” 2015 IEEE International Conference on Communications (ICC), London, 2015, pp. 2620-2625, doi: 10.1109/ICC.2015.7248720.
[3] L. Lampe, R. Schober and M. Jain, “Noncoherent sequence detection receiver for Bluetooth systems,” in IEEE Journal on Selected Areas in Communications, vol. 23, no. 9, pp. 1718-1727, Sept. 2005, doi: 10.1109/JSAC.2005.853791.
[4] ETSI ETS 300 401, “Radio broadcasting systems; DAB to mobile, portable and fixed receivers,” 1997.
[5] M Lopez-Morales, K Chen Hu, A Garcia Armada, “Differential Data-aided Channel Estimation for Up-link Massive SIMO-OFDM”, IEEE Open Journal of the Communications Society -> in press.
[6] K Chen Hu, L Yong, A Garcia Armada, “Non-Coherent Massive MIMO-OFDM Down-Link based on Differential Modulation”, IEEE Trans. on Vehicular Technology -> in press.
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About Ana García Armada, PhD:
- Spanish version (updated Jan 2020)
- English version (updated Jan 2020)
- Google Scholar: link
- ResearchGate: link
- Academia.edu: link
T-Mobile shutters Sprint’s 5G network; OpenSignal 5G User Experience report highlights
As expected following the April 1st close of T-Mobile’s acquisition, Sprint’s 5G network (which uses 2.5GHz mid-band spectrum) has been deactivated while the “new T-Mobile” works to re-deploy it across its own network.
The integration of the Sprint mid-band spectrum is a key part of T-Mobile’s 5G strategy, which aims to combine low-band 600MHz spectrum for broad, nationwide 5G coverage with faster but lower-range midband (Sprint’s 2.5GHz network) and short-range mmWave networks for a balance of coverage and speed.
T-Mobile has already deployed its new 2.5GHz spectrum in New York, the first market to benefit from the wireless network operator’s spectrum in low-, mid-, and millimeter wave bands. The operator’s 2.5GHz 5G is also live in “parts” of Chicago, Houston, Los Angeles, New York, and Philadelphia.
Most existing Sprint customers won’t be able to use their current devices going forward to access 5G. Newer devices that feature Qualcomm’s X55 modem, like the Galaxy S20 5G lineup, will still be able to access the 2.5GHz 5G when they relaunch as part of the new T-Mobile’s 5G network (along with the rest of T-Mobile’s low-band and mmWave 5G spectrum). T-Mobile is offering credits for affected customers to lease a new 5G device.
“We are working to quickly re-deploy, optimize and test the 2.5 GHz spectrum before lighting it up on the T-Mobile network. In the meantime, legacy Sprint customers with compatible devices can enjoy T-Mobile’s nationwide 5G network,” a T-Mobile spokesperson said.
According to data from a new Opensignal 5G User Experience report, customers using T-Mobile’s mid-band 5G are benefitting from average download speeds of around 330Mbps. The mobile analytics company ranks T-Mobile first for 5G availability; with customers receiving a 5G signal around twice as often as AT&T and 56 times more than Verizon.
T-Mobile’s press release about the Opensignal report said customers are seeing average download speeds of 330 Mbps on its mid-band 2.5 GHz network.
From that OpenSignal report:
T-Mobile wins the 5G Availability award, as its 5G users spend 22.5% of time connected to 5G:
The time connected to a 5G service is extremely important if users are to enjoy all of 5G’s benefits. In the U.S., T-Mobile won the 5G Availability award by a large margin with Sprint and AT&T trailing with scores of 14.1% and 10.3%, respectively. Verizon users saw their extremely fast 5G service 0.4% of the time because of the limited geographical reach of the mmWave wireless technology Verizon currently relies upon for 5G and the early stage of the 5G deployment.
Sprint’s 5G users’ experience is already changing as new T-Mobile combines its network capabilities:
When we previously looked at the 5G Download Speed of Sprint’s users some time ago we saw average 5G speeds of 114.2 Mbps reflecting the mid-band 5G wireless spectrum Sprint relied upon. But following the completion of T-Mobile’s acquisition of Sprint, the new T-Mobile is starting to provide Sprint 5G users with access to old T-Mobile’s 600MHz spectrum and so average 5G speeds are now 49.5 Mbps but 5G Availability has risen from 10.3% to 14.1% of time. T-Mobile is still in the process of merging its original network with Sprint and we expect the mobile network experience of Sprint users will continue to change for some time.
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“Building the fastest 5G network is easy if you only cover less than 50 square miles. Opensignal’s report shows that only T-Mobile is doing the hard work to deliver BOTH 5G coverage and speed. And we’re just getting started,” said Neville Ray, President of Technology at T-Mobile.
“With the addition of Sprint, the Un-carrier’s 5G is getting bigger, better and faster every day, moving quickly on our mission to build the world’s best 5G network, one unlike any other, to people all across the country!”
T-Mobile and Sprint were finally cleared to merge on April 1st, following discussions which began in 2013.
To appease regulators, T-Mobile agreed to sell Sprint’s prepaid business, Boost Mobile, and Virgin Mobile to Dish network for $1.4 billion. The deal also included selling Sprint’s entire 800 MHz portfolio of spectrum to Dish. Those deals formally completed yesterday.
Last month, T-Mobile asked California’s Public Utilities Commission (CPUC) to ease other conditions it agreed to in order for the merger to be granted – including job creation promises following the COVID-19 pandemic, average 5G coverage and speed commitments, and to remove a “burdensome” third independent test of its network.
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References:
T-Mobile switches off Sprint’s 5G network following $26.5 billion merger
https://www.opensignal.com/reports/2020/06/usa/mobile-network-experience-5g
ETNO, GSMA: EU should adopt “fresh approach” to support fiber & 5G investments; GSMA says 5G SA coming soon?
The European telecom network operators industry group ETNO together with the GSMA have called on the EU to make support for fiber optics communications and 5G investments part of the bloc’s economic recovery plans. In a joint statement to mark the start of the German presidency of the EU, the associations said a fresh approach is needed to ensure the focus is on closing the digital divide and that plans to alleviate that should not become bogged down in regulatory discussions.
“We encourage all institutions to take stock of the socio-economic context and shift regulatory modes from ‘business-as-usual’ to a fresh and comprehensive approach aimed at unleashing the full power of network investment, at full scale and at full pace,” the statement said.
The joint communique then delineated ways policymakers can support the investment in improved connectivity for the EU:
- Spectrum auctions are timely and conditions for spectrum assignment support network deployment. This includes taking a long-term view to spectrum prices, rather than imposing punitive fees that hamper 5G investment. Also, access and coverage obligations should not diminish the speed and scale of investment in network roll-out;
- Sharing agreements for Radio Access Network (RAN) are supported and incentivised, so that they contribute to a speedy 5G deployment;
- All fibre investment models are adequately incentivised at the national level, including co-investment and other forms of partnerships;
- Innovative infrastructure solutions, such as cloud, edge and quantum computing, are given the appropriate support;
- Future EU initiatives dramatically reduce roll-out costs for both mobile and fixed networks. This should tackle, for example, unreasonable costs for using public ground as well as complex authorization procedures for both fixed and mobile networks;
- Open and interoperable interfaces in the RAN are supported. Initiatives such as Open RAN have the potential to support Europe’s multi-vendor approach, while reducing deployment costs, further strengthening the security of the equipment and unleash more network innovation.
The most important thing is helping grow adoption of the new technologies by citizens and businesses, the statement said. This includes supporting digital skills education and training. “Finally, workers of all ages should be put in the condition to develop the necessary digital skills – both through upskilling and reskilling – to thrive in innovative and fast-paced markets.”
Demand stimulus measures can also help bring digital services to public sector organizations like schools, hospitals and local administrations. That would not only support Europe’s economic recovery, but also can contribute to the EU’s climate goals.
The GSMA and ETNO also called on the EU governments to combat the attacks against telecom infrastructure and misinformation surrounding 5G. To date they have counted over 180 arson attacks against mobile antennas in 11 countries.
Media Inquiries:
Alessandro Gropelli, ETNO – [email protected] 0032 476 9418 39
Noelle Knox, GSMA Europe – [email protected] 0032 470 45 2941
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Separately, GSMA says “5G Stand Alone to Become Reality“:
“The deployment of fully virtualized networks using 5G Stand Alone Cores, thereby facilitating Edge Computing and Network Slicing, will enable enterprises and governments to reap the many benefits from high throughput, ultra-low latency and IoT to improve productivity and enhance services to their customers,” said Alex Sinclair, Chief Technology Officer, GSMA.
“5G Stand Alone Option 2 can meet various and more stringent requirements and provide optimal and differentiated solutions, thereby empowering more businesses and unlocking the potential of many services. 5G is changing our society and life,” said Liu Guiqing, Executive Vice President of China Telecom.
“NTT DOCOMO has been actively promoting virtualisation of our core network; we believe that this virtualisation technology is already mature and that our operational know-how will be our advantage. In the future we expect to build dedicated networks, optimised for consumer use cases, such as AR /VR and gaming,” said Hiroyuki Oto, General Manager of Core Network Development Department, NTT DOCOMO, Inc.
The latest version of the 5G SA guidelines ‘5G Implementation Guidelines: SA Option 2 will be released 30th June at 17:00 Beijing time during Thrive China, a new virtual event from the GSMA.
NOTE that those GSMA guidelines come before 3GPP Release 16 5G Architecture (including 5G Core) spec 23.501 is finalized/frozen at 3GPP’s July 2020 meeting. It seems there will be many versions of 5G core networks:
Alex Quach, VP of Intel’s Data Platforms Group: “The way different service providers implement their 5G core is going to vary. Every service provider has unique circumstances. The transition to a new 5G core is going to be different for every operator.”
Asked if SK Telecom has now completed its 5G Standalone core network, the South Korean carrier was vague in an email reply to FierceWireless. “To commercialize standalone 5G service in Korea, we are currently making diverse R&D efforts including conducting tests in both lab and commercial environment. Our latest achievements include the world’s first standalone (SA) 5G data session on our multi-vendor commercial 5G network.
fiercewireless.com/operators/sk-t
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GSMA also states that:
Mobile connections, including cellular IoT as of 1 July 2020 =8,805,024,140 (not the 20B Ericsson and others predicted for 2020)
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References:
https://etno.eu/news/all-news/8-news/678-joint-statement-telecoms-eu-recovery.html
https://etno.eu/news/all-news.html