IET Lecture by Prof. Andy Sutton: Point to Point Microwave Radio Systems

Point to point microwave radio systems have been with us for more than eighty years, yet they rarely attract much attention in an era where fibre dominates network planning and satellite systems continue to develop at pace. At a recent IET Anglian Coastal Local Network event, Prof. Andy Sutton delivered an excellent lecture that brought these fixed radio links back into the spotlight. His talk explored the history, engineering and future of microwave and millimetre wave links, reminding us why they remain essential for transmission networks in the UK and around the world.

The story begins with the national microwave radio network of the 1970s, with the BT Tower at its centre. These early deployments supported long links across the country and laid the foundation for many of the design principles still used today. While the landscape has changed significantly, the fundamentals of fixed radio communication continue to be shaped by spectrum availability, propagation characteristics and careful engineering.

Microwave links depend on a wide range of bands, from the lower 6 GHz region through to 80 GHz E-band. The choice of frequency affects everything from link length to susceptibility to atmospheric absorption. As Andy explained, a link designer must consider not just free space path loss, but also Fresnel zone clearance, rainfall intensity and antenna characteristics. The slides included a worked example that showed the impact of frequency and distance on the radius of the Fresnel zone and highlighted the need for adequate clearance to maintain availability over time.

The talk moved on to modern access radio systems, where compact rooftop nodes and all-outdoor radios have become common. These systems rely on careful use of vertical and horizontal polarisations, often enabled through XPIC technology. XPIC allows separate data streams to coexist on the same frequency using orthogonal polarisations, effectively doubling link capacity when conditions allow. This is paired with adaptive coding and modulation, which enables the radio to shift modulation schemes according to link quality. The result is a more resilient and efficient link compared to older fixed-modulation systems.

Capacity planning is a balancing act that involves radio channel bandwidth, modulation choice and the number of aggregated carriers. Wider channels and higher order modulation support multi-gigabit throughput, although this introduces penalties in transmit power and receiver sensitivity. The trade-offs are central to radio design and determine the type of equipment used, whether through a separate indoor and outdoor unit or an integrated all-outdoor system.

Andy also covered the practical elements of radio link planning, such as antenna selection, path profiling, waveguide losses and typical link budget calculations. A link planning example using a 32 GHz radio demonstrated the relationship between transmit power, antenna gain, free space loss and fade margin for a target availability of 99.99 percent. The discussion tied together the theoretical foundations with real-world engineering and illustrated how access radios are designed for street-level backhaul scenarios.

The lecture then moved to millimetre wave systems, particularly E-band radios that operate around 70 and 80 GHz. These links offer enormous capacity over shorter distances and are increasingly used for dense urban backhaul and enterprise connectivity. The slides included examples of network topologies showing how microwave and fibre can be combined to meet different deployment objectives.

A substantial part of the presentation focused on trunk or core microwave radio systems. These high-capacity, high-availability links support long distances and historically formed the backbone of national networks. Although demand for trunk links has reduced as fibre has spread, they still exist in challenging environments. In the UK, many trunk links remain operational in Scotland and island regions where terrain and geography limit fibre deployment. The lecture covered branching networks, duplexers, waveguide installations and space diversity techniques, all of which contribute to the reliability of long-haul links.

Looking ahead, research continues into new frequency bands, wider channels, higher modulation schemes and improved radio hardware. These advances will support even greater capacities, with millimetre wave links expected to reach 100 Gbps over short distances. Microwave radio may no longer be the headline technology it once was, but the field continues to push boundaries and remains an essential part of modern communication networks.

Andy’s lecture was a comprehensive tour of the past, present and future of point to point microwave systems. For anyone working in transmission, mobile networks or wireless engineering, it served as a valuable reminder of the depth of innovation in this area and its continued relevance in the broader ecosystem.

If you would like to explore the material in more detail, the slides from the event are available here and the video can be seen here. Both are well worth a look.

Related Posts:

• Connectivity Technology Blog - 5G Demystified; the What, When and Where by Prof. Andy Sutton, BT
• The 3G4G Blog - Prof. Andy Sutton: Backhauling the 5G Experience - Jan 2020
• The 3G4G Blog - Prof. Andy Sutton: 5G Radio Access Network Architecture Evolution - Jan 2019
• The 3G4G Blog: 5G Network Architecture, Design and Optimisation - Jan 2018
• The 3G4G Blog: 5G Network Architecture and Design Update - Jan 2017
• The 3G4G Blog - CWHeritage Talk: The History of Synchronization in Digital Cellular Networks 

Towers, Masts and Poles: The Backbone of Telecom Infrastructure

We often walk past them without a second glance—towers, masts, and poles that quietly support the vast web of our modern telecommunications networks. But behind these unassuming structures lies a fascinating history and a critical role in enabling everything from phone calls to television broadcasts.

In a brilliant lecture hosted by the IET, Professor Nigel Linge (with support from Professor Andy Sutton) takes us on a journey through the evolution of telecom infrastructure. Starting from ancient beacons and Napoleonic-era semaphores to the iconic BT Tower and long wave radio transmitters, the talk connects the dots across centuries of innovation.

On Friday 28th March I delivered a lecture to #TheIET at Savoy Place in London on the subject of "Telecom Towers, Masts, and Poles". Celebrating one of the visible faces of the telecoms industry. It was recorded by IETtv and can be viewed here: https://t.co/2MULwtRp5x pic.twitter.com/aD4cK7zyZU

— Nigel Linge (@NigelLinge) April 7, 2025

The lecture touches on early telegraphy using bare copper wires strung on porcelain insulators, the dawn of voice telephony, Marconi’s pioneering wireless transmissions, and the growth of regional radio and TV broadcasting in the UK. It also highlights how microwave relays and horn-reflector antennas became vital to long-distance communication, with the BT Tower serving as a key hub in the national network.

Whether it’s the humble telegraph pole or the towering masts on hilltops, each structure plays a part in delivering connectivity. This presentation offers a timely reminder of the physical foundations of our digital world—often overlooked, yet essential to our everyday lives.

Watch the full lecture below:

You can also read an article by them detailing many things covered in the lecture here.

Related Posts:

• The 3G4G Blog: Explaining Telecoms
• The 3G4G Blog - Tutorial: A Quick Introduction to 3GPP
• The 3G4G Blog: The History of Camera Phones
• The 3G4G Blog - Prof. Andy Sutton: Backhauling the 5G Experience
• The 3G4G Blog: A Primer on Pagers
• The 3G4G Blog - CWHeritage Talk: The History of Synchronization in Digital Cellular Networks
• The 3G4G Blog: The Iconic British Red Phone Boxes
• The 3G4G Blog: 30 years of the mobile phone in the UK 

Prof. Andy Sutton: Backhauling the 5G Experience - Jan 2020

Prof. Andy Sutton has shared quite a few presentations and talks on this blog. His presentations from the annual 'The IET 5G Seminar' has made it to the top 10 for the last 3 years in a row. His talk from 2019, 2018 & 2017 is available for anyone interested.

The title of this year's conference was '5G 2020 - Unleashed'. The details are available here and the video of all the talks are here. As always, the slides and video is embedded below.

Slides

Prof. Andy Sutton: Backhauling the 5G Experience from 3G4G

Video


There are a lot of bands that keep on getting mentioned, especially in relation to backhaul. Here is a summary of these bands that would come handy.

Related Posts:

• Prof. Andy Sutton: 5G Radio Access Network Architecture Evolution - Jan 2019
• Prof. Andy Sutton: 5G Network Architecture, Design and Optimisation - Jan 2018
• Prof. Andy Sutton: 5G Network Architecture and Design Update - Jan 2017
• Prof. Andy Sutton #CWHeritage Talk: The History of Synchronization in Digital Cellular Networks
• Connectivity Technology Blog: An Introduction to Different Types of Backhaul
• 5G Evolution with Matthew Baker, Nokia
• Exploring Network Convergence of Mobile, Broadband and Wi-Fi
• 5G and Fixed-Mobile Convergence (FMC)

Summary of #CWTEC 2019 Conference: 5G, Satellites & Magic MIMO

I was involved in helping organise yet another CW TEC conference this year. The topic was quite interesting and we had some brilliant speakers. Some of the excellent presentations were shared too, links below. Here is a very quick summary of the event, linking also to couple of excellent summaries below.

The topic was a bit unusual and it rhymed very well with the attendees which were from many different backgrounds, from 5G, communications, satellites, electronics, T&M companies, etc. Here is the opening video that will show you the motivations behind this



The day started with a breakfast briefing from Cambridge Consultants that looked at how Massive MIMO is the key to unlocking 5G User Experiences. Presentations available here.

#CWTEC is underway with a thorough breakfast briefing from @CambConsultants. What is 5G NR? What is #MassiveMIMO? How about #beamforming? Delegates get up to speed with the day’s subject area before talks kick off at 10AM. We can’t wait! pic.twitter.com/lGELOWeZk2

— Cambridge Wireless (@cambwireless) September 26, 2019

Session 1 was titled "What has Massive MIMO ever done for us?". The narrative for the session was as follows:

Clearly the desire for more and more capacity in cellular networks has driven the industry to find more and more novel techniques. The work done over the years and boosted by Tom Marzetta’s article titled “Noncooperative Cellular Wireless with Unlimited Numbers of Base Station Antennas” has set high expectations for this emergent technology, so much so the term Magic MIMO has been coined. However, how significant is it into today’s early 5G rollout and what can we expect over the coming years? Are there still further enhancements we should expect to see?

There were 3 talks as follows:

• Sync Architectures for 5G NR by Chris Farrow, Technical Manager, Chronos Technology (slides)
• Three UK’s RAN transformation: Spectrum, RAN architecture strategy, Why? by Dr Erol Hepsaydir, Head of RAN and Devices Strategy and Architecture, Three UK (slides)
• Active antenna systems in RAN: performance, challenges and evolution by Anvar Tukmanov, Wireless Research Manager, BT (slides)

Anvar Tuknanov from ⁦⁦@bt_uk⁩ showing improvement in communications capacity as technology has evolved to 5G M-MIMO. ⁦@cambwireless⁩ #CWTEC ⁦@CGI_UKNEWS⁩ #ExperienceCGI pic.twitter.com/IZXJk2n6u4

— Andrew Palmer (@AndrewPalmerCGI) September 26, 2019

Session 2 looked at "Non-Terrestrial & Hybrid Networks". The narrative for the session was as follows:

There are different initiatives underway to make satellite and other non-terrestrial networks as part of 5G. In addition, many different mobile operators have demonstrated compelling use-cases with drones, balloons and other aerostats. Other innovative approaches like European Aviation Network uses a hybrid-network using terrestrial network supported by a satellite connection as a backhaul for in-flight Wi-Fi. In addition to latency, what other challenges are stopping mass adoption of Non-terrestrial and Hybrid networks? What about advanced features like slicing, etc.?

There were 3 talks as follows:

• Opportunities for blending terrestrial and satellite technologies by Dr Jaime Reed, Director, Consulting, Space, Defence and Intelligence, CGI (slides)
• Non-terrestrial Networks: Standardization in 5G NR by Dr Yinan Qi, Senior 5G Researcher, Samsung R&D Institute UK (slides)
• Satellites and 5G: A satellite operator’s perspective by Simon Watts, Principal Consultant, Avanti Communications (slides)

A fantastic technical in-depth session on Non-Terrestrial Networks (NTN) by Yinan Qi, Samsung. Loved it @TMGB
#CWTEC pic.twitter.com/QUpxA3wKj9

— Zahid Ghadialy (@zahidtg) September 26, 2019

Session 3 looked at "5G: A Catalyst for Network Transformation". The narrative was as follows:

5G has set high expectations in the user as well as operator community. While eMBB can be supported with an upgrade of existing 4G infrastructure, URLLC and mMTC may require massive change in the network architecture. Operators have already started the transformation process with backhaul upgrades, new data centers, distributed core and cloud rollouts, etc. How are networks evolving to accommodate these deep changes? What other changes will be required in the network to support the growth until the next new generation arrives?

This session featured 3 talks as well

• An Introduction to Open RAN Concept by Zahid Ghadialy, Senior Director, Strategic Marketing, Parallel Wireless UK & EMEA (slides)
• Powering the successful deployment of 5G infrastructure by David George, Vice President of EMEA and APAC, Sitetracker (slides)
• The 5G transformation: no sweet without sweat by Antonella Faniuolo, Head of Network Strategy, Planning, Digital & Optimisation, Vodafone (slides)

We loved @zahidtg’s #OpenRAN diagrams in his session at #CWTEC this afternoon. Good explanation of why OpenRAN matters and how it actually works. #5G @Parallel_tw pic.twitter.com/DTna4pC7bA

— Cambridge Wireless (@cambwireless) September 26, 2019

The final session topic was "Getting ready for Beyond-5G Era". The narrative was as follows:

Many technologies like Full duplex, etc. that were originally intended to be part of 5G were not able to make it into the standards. Along with these, what other revolutionary changes are needed to make Beyond-5G technologies not only fulfil the vision, ambition and use-cases that were originally envisaged for 5G but to take it a step further and make it a game changer.

This session featured 3 talks as well, as follows:

• Thinking Beyond 5G: Projects and Initiatives by Alan Carlton, Vice President, InterDigital Europe (slides not available)
• 5G Evolution: Progressive enhancement and new features for new markets by Matthew Baker, Head of Radio Physical Layer and Coexistence Standardization, Nokia (slides)
• Why 6G’s design goals need far more than just radio & core innovation by Dean Bubley, Analyst & Futurist, Disruptive Analysis (slides not available)

3GPP Release - Technology
99 - UMTS (3G)
4
5 - HSDPA (3.5G)
6 - HSUPA
7 - HSPA+
8 - LTE (3.9G)
9
10 - LTA-A (4G)
11
12
13 - LTE-A Pro (4.5G)
14
15 - 5G
16
17
18 - 5.5G?
19
20
21 - 6G?#CWTEC #3G4G5Gpic.twitter.com/vQi5Dhfsno

— 3G4G (@3g4gUK) October 8, 2019

And my personal highlight was that I launched World's first coloured 5G tie

Did I mention I am launching my World's First Coloured 5G Tie that caters for all different implementations of 5G 😁 #CWTEC@cambwireless @3g4gUK @Parallel_tw @3GPPLive @IBTwi @AndrewPalmerCGI @alainmouradUK pic.twitter.com/j0ebPnSxaB

— Zahid Ghadialy (@zahidtg) September 26, 2019

Hopefully you found the presentations shared as useful. Please also read the summaries of CWTEC provided below.


Related Articles:

• CW Technology & Engineering Conference Review by CW (Cambridge Wireless)
• CWTEC: 5G, Massive MIMO and Satellites by David Chambers, ThinkSmallCell
• Dean Bubley made a nice Twitter Thread on CWTEC here.
• All the information about the conference is available here.

5G SpeedTests and Theoretical Max Speeds Calculations

Right now, Speed Tests are being described as 5G killer apps.

SpeedTests are the 5G killer app right now 😂. Thread 👇 https://t.co/jjyk0PheT6

— 3G4G (@3g4gUK) July 2, 2019

A good point by Benedict Evans

What was the killer app for 3G? The internet. What’s the killer app for 5G? More internet, mostly.

— Benedict Evans (@benedictevans) January 18, 2019

Everyone is excited and want to see how fast 5G networks can go. If you use Twitter, you will notice loads and loads of speed tests being done on 5G. An example can be seen above.

I recently heard Phil Sheppard, Director of Strategy & Architecture, '3 UK' speak about their 5G launch that is coming up soon. Phil clearly mentioned that because they have a lot more spectrum (see Operator Watch blog post here and here) in Capacity Layer, their 5G network would be faster than the other UK operators. He also provided rough real world Peak Speeds for Three and other operators as can be seen above. Of course the real world speeds greatly depend on what else is going on in the network and in the cell so this is just a guideline rather than actual advertised speeds.

I have explained multiple times that all 5G networks being rolled out today are Non-Stand Alone (NSA) 5G networks. If you don't know what SA and NSA 5G networks are, check this out. As you can see, the 5G NSA networks are actually 4G Carrier Aggregated Networks + 5G Carrier Aggregated Networks. Not all 4G spectrum will be usable in 5G networks but let's assume it is.

To calculate the theoretical maximum speed of 5G NSA networks, we can calculate the theoretical maximum 4G Network speeds + theoretical maximum 5G Network speeds.

I have looked at theoretical calculation of max LTE Carrier Aggregated Speeds here. Won't do calculation here but assuming 3CA for any network is quite possible.

I also looked at theoretical calculation of 5G FDD New Radio here but then found a website that helps with 5G NR calculation here.

If we calculate just the 5G part, looking at the picture from Three, we can see that they list BT/EE & O2 speeds as 0.61 Gbps or 610 Mbps, just for the 5G part.

Looking at the calculation, if we Input Theoretical max values in this equation:

Calculating just for DL

J - number of aggregated component carriers,
maximum number (3GPP 38.802): 16
input value: 1

v(j)Layers - maximum number of MIMO layers ,
3GPP 38.802: maximum 8 in DL, maximum 4 in UL
input value: 8

Q(j)m modulation order (3GPP 38.804)
For UL and DL Q(j)m is same (QPSK-2, 16QAM-4, 64QAM-6, 256QAM-8)
input value: 8 (256QAM)

f(j) Scaling factor (3GPP 38.306)
input value: 1

FR(j) Frequency Range 3GPP 38.104:
FR1 (450 MHz – 6000 MHz) и FR2 (24250 MHz – 52600 MHz)
input value: FR1

µ(j) -value of carrier configuration (3GPP 38.211)
For DL and UL µ(j) is same (µ(0)=15kHz, µ(1)=30kHz, µ(2)=60kHz, µ(3)=120kHz)
input value: 0 (15kHz)

BW(j)- band Bandwidth, MHz (3GPP 38.104),
should be selected with Frequency Range and µ(i) configuration:
input value: BW:40MHz FR1 µ:15kHz:

Enter a PRB value (if other)
default: 0

Rmax (if you don't know what is it, don't change)
Value depends on the type of coding from 3GPP 38.212
(For LDPC code maximum number is 948/1024 = 0.92578125)
default: 0.92578125

*** Only for TDD ***
Part of the Slots allocated for DL in TDD mode,
where 1 = 100% of Slots (3GPP 38.213, taking into account Flexible slots).
Calculated as: the number of time Slots for DL divided by 14
default value: 0.857142

Part of the Slots allocated for UL in TDD mode,
where 1 = 100% of Slots (3GPP 38.213, taking into account Flexible slots).
Calculated as: 1 minus number of Slots for DL
default value: 0.14285800000000004

Calculated 5G NR Throughput, Mbps: 1584


As you may have noticed, BTE/EE has 40 MHz spectrum while Vodafone in UK have 50 MHz of spectrum.

Changing
BW(j)- band Bandwidth, MHz (3GPP 38.104),
should be selected with Frequency Range and µ(i) configuration:
input value: BW:50MHz FR1 µ:15kHz:

Calculated 5G NR Throughput, Mbps: 1982

Now Three UK has 100 MHz, immediately available for use. So changing

µ(j) -value of carrier configuration (3GPP 38.211)
For DL and UL µ(j) is same (µ(0)=15kHz, µ(1)=30kHz, µ(2)=60kHz, µ(3)=120kHz)
input value: 1 (30kHz)

BW(j)- band Bandwidth, MHz (3GPP 38.104),
should be selected with Frequency Range and µ(i) configuration:
BW:100MHz FR1 µ:30kHz:


Calculated 5G NR Throughput, Mbps: 4006

In theory, a lot of speed is possible with the 100 MHz bandwidth that Three will be able to use. We will have to wait and see who can do a theoretical max SpeedTest. In the meantime remember that a 1Gbps speed test will use over 1 GB of data.



Related Posts:

• Tutorial on 5G Spectrum
• Theoretical Throughput Calculation of FDD 5G New Radio (NR)
• Theoretical calculation of EE's announcement for 429Mbps throughput

5G and Electromagnetic energy (EME)

Every time a new generation of mobile technology is being rolled out, there are scare stories about the radiation, cancer, etc. I last wrote a post on this topic back in 2011 and also in 2009. The main thing that has changed since is that 5G is being rolled out today as 4G was being rolled out then.

The Australian operator Telstra recently completed extensive testing of their 5G network infrastructure in real-world settings using commercially available 5G devices, and their data confirms two things. Firstly, the 5G technology produces electromagnetic energy (EME) levels at around 1000 times below the safety limits in many cases. Secondly, all the testing has found 5G EME levels to be similar to 3G, 4G and Wi-Fi. You can read the details and complete report here.

Last month I went to a seminar titled 'Update on Current Knowledge of RF Safety', organised by CW Radio Technology Group and National Register of RF Workers. Richard Hargrave from BT explained the challenge with compliance when a 5G carrier is added.

The implications as he said are:

• Some sites in urban areas become increasingly difficult to provide required capacity while maintaining compliance using standard designs
• Significant time and cost can be associated with works necessary to ensure compliance – new planning permissions, physical structures, new site acquisition etc
• As 5G is deployed further, particularly as additional spectrum is auctioned in 700MHz and 3.6-3.8GHz bands these problems will be exacerbated

His presentation is available here. Another presentation from Moray Rumney, asking some tough question on 5G safety is available here. Simon Rockman has written a summary of this seminar on Forbes, here.

I heard the Swiss operator Sunrise mentioning in a presentation at 5G World 2019 that the EMF limit in Switzerland is 10 times stricter than the rest of the world. This implies that 5G in Switzerland is extremely safe. The slide from the presentation can be seen in the pic above.

We also have couple of related videos on this topic, maybe of interest:

• Non millimeter Wave (mmWave) 5G
• 5G Spectrum - Short Version
• 5G Spectrum - Long Version

Further Reading:

• Electromagnetic energy (EME) - Telstra Consumer Advice
• 5 surveys of 5G show EME levels well below safety limits - Telstra
• Is 5G Dangerous? - Simon Rockman, Forbes
• 5G Dangers: Myth or Science? - Apis Training
• 5G health risks: What's the evidence? - BBC

Presentations on Macro Cells and Millimetre-wave Technology from recent CW (Cambridge Wireless) events

CW (Cambridge Wireless) held a couple of very interesting events from 2 very popular groups.

The first one was on "5G wide area coverage: macro cells – the why and the how". This event looked at the design and optimisation of the macro cell layer and its role within future heterogeneous networks. You can access the presentations for limited time on CW website here.

The presentations available are:

• Macro Cell developments that support LTE evolution and 5G deployments by Colin Bryce, Commscope
• Review of current macro network site types and design by Andy Sutton, British Telecommunications
• Smart rollout to maximise ROI by Mike Page, Radio Design
• Strategic planning: an overview of the role of the macro cell by Iris Barcia, Keima
• How massive MIMO can deliver the promise of new 5G Radio Networks by George Grayland, 5GFutures

Related posts that may be of interest:

• Keima: Automated 4G / 5G HetNet Design
• Prof. Andy Sutton: 5G Radio Access Network Architecture Evolution - Jan 2019
• #CWHeritage Talk: The history of synchronisation in digital cellular networks

Commercialising millimetre-wave technology - Presentations from @cambwireless #CWRadioTech event last week available now: https://t.co/PJbrBiJ8UR #4G #5G #Spectrum #Frequencies pic.twitter.com/6naiUSK1qw

— 3G4G (@3g4gUK) May 21, 2019

The second one was on "Commercialising millimetre-wave technology". The event reviewed the commercial opportunities at millimetre-wave frequencies, what bands are available and what licensing is needed. You can access the presentations on CW website for limited time here.

The presentations available are:

• ‘Measurements, Modelling and Testing Millimetre Wave Communication Systems’ by Mark Beach, University of Bristol (Communication Systems & Networks Research Group)
• The Design of a Plastic Packaged Front-end IC for mmWave 5G by Liam Devlin, Plextek RFI
• Design Considerations for the Realisation of Cost-Effective, High-Performance mmWave PCBs by James Henderson, Plextek
• Millimetre wave wireless for improved wireless connectivity in Transport by Mark Barrett, Blu Wireless Technology
• Unlicensed, unlimited: 60GHz mmWave’ by Paul Morris, CCS
• Millimetre-Wave Circuit Simulation Challenges’ by David Morris, Keysight Technologies
• Use Cases & Enabling 5G NR Technologies by Mark Beach, University of Bristol (Communication Systems & Networks Research Group)
• Whitepaper by Paul Holes, Anritsu

We recently made a video to educate people outside our industry about non-mmWave 5G. It's embedded below.

Update on UK's Emergency Services Network (ESN) from #BAPCO2019

I have discussed about the UK's Emergency Services Network (ESN) multiple times but I manged to hear about the progress first hand this week. Bryan Clark, ESN Programme Director, Home Office gave a keynote address at BAPCO on Day 2 and the title of his presentation was "2019: The year vision becomes reality"

British APCO or BAPCO Annual Conference and Exhibition 2019 was going to be a big launchpad for the ESN network. The ESN LinkedIn post said "Representatives from ESN and EE will be on hand to discuss coverage and ESN Assure. See an installation of the ESN Gateway solution within a police car, plus a live demonstration showing how ESN coverage can be extended from a vehicle into a building. We’ll also have a ‘Motorola Zone’ where you can watch demos of Kodiak and the ESN self-service portal – and a large touchscreen demo of the Samsung ESN Galaxy"

Bryan started by cracking a joke about people referring to 'ESN' as 'ES When' programme because it has been delayed multiple times. He said straight in the beginning that he going to talk about what the ESN programme is doing now and what comes next.

He started with this short video, embedded below but detailed info available on this LinkedIn post

x

So here is a short summary of the talk:

• There are roughly 350,000 customers of this service
• There are 137 separate organizations that will take advantage of this new this new technology. 
• There are couple of vehicles in the display area (pic on the top and video below) and roughly 50,000 vehicles that need to have a kit
• Over 100 aircraft need to have an air network access that currently isn't there. 
• There are nearly 30 direct suppliers to the program and that doesn't include the whole supply chain through each of those suppliers.
• Looking at the coverage, there is a commitment to providing a signal along half a million (0.5 million) kilometers of roads in England, Scotland & Wales. It extends 12 nautical miles out to sea and 10,000 feet in the air right across England, Scotland & Wales.
• In London alone there are over 400 kilometres of tunnels that were actually almost finished cabling out.
• 300 masts are being built as part of the ESN programme to extend services into remote areas.
• EE has extended their network by adding 700 additional masts. 
• Thousands of special locations will need to have effective access to ESN network
• ESN is a large programme so it's hardly surprising that it's very late. It's Bryan's job over the past 10 months to work out how to get it back on track. 
• People are going through quite a detailed review of where ESN has got to in terms of next steps. 
• The programme now has a very clear and approved plan to complete the technical element of the work, most of it should be done by late summer next year.
• One of the first products, Assure, is a way of testing the effectiveness of the network in the field. 
• A demonstration of Push-To-Talk (PTT) on a 4G network will be demoed within 3 weeks.
• This is the first generation end-to-end solution
• Emergency services is critical national infrastructure so any new solution can only replace the legacy once we are absolutely confident that we've got an effective replacement
• Even though the technical piece is quite challenging, when you compare it to the business change that follows, the technical part looks pretty simple. 
• To ensure that everything works effectively operationally, plans are in place but more detailed plans are going to follow in the coming three to four months.
• Individual components are already being tested in the field
• Programme deployment should start by the end of 2019 in terms of having basically completed laying the core components and a clear plan will be in place for how to test in an operational context. 
• The ESN programme is not only responsible for the replacement solution but also for operations to date based on the Airwave contract with Motorola currently
• The number one priority is to provide critical voice communications of sufficient quality that people can rely on in the field and enable them to move away from the TETRA technology that served them so well. So we aren't going anywhere until we've got rock solid critical voice communications. It's our number one priority, simply because people's lives depend on it.

The following are various videos from the ESN demo area. The Gateway device (which is a mobile small cell) is supplied by Parallel Wireless*.



In case you missed BAPCO, Ken Rehbehn, a very well known Industry Analyst who works as a Principal Analyst at Critical Communications Insights and is also Montgomery County Firefighter/EMT, shared his observations and reflections from conference. Very grateful for his interview which is embedded below



Further Reading:

• Building a new critical communications network that keeps you safe - Bryan Clark, Programme Director, Emergency Services Network

Related posts:

• 3G4G Small Cells Blog: Meshing for BYOC (Bring Your Own Coverage)
• The 3G4G Blog: Quick tutorial on Mobile Network Sharing Options
• The 3G4G Blog: A practical use of MOCN in ESN
• The 3G4G Blog: EE's vision of Ultra-Reliable Emergency Network
• The 3G4G Blog: Update from 3GPP on LTE & 5G Mission Critical Communications

*Full Disclosure: I work for Parallel Wireless as a Senior Director in Strategic Marketing. This blog is maintained in my personal capacity and expresses my own views, not the views of my employer or anyone else. Anyone who knows me well would know this.

Prof. Andy Sutton: 5G Radio Access Network Architecture Evolution - Jan 2019

Prof. Andy Sutton delivered his annual IET talk last month which was held the 6th Annual 5G conference. You can watch the videos for that event here (not all have been uploaded at the time of writing this post). His talks have always been very popular on this blog with the last year talk being 2nd most popular while the one in 2017 was the most popular one. Thanks also to IET for hosting this annual event and IET Tv for making this videos available for free.

The slides and video is embedded below but for new starters, before jumping to this, you may want to check out about 5G Network Architecture options in our tutorial here.

Prof. Andy Sutton: 5G RAN Architecture Evolution - Jan 2019 from 3G4G

As always, this is full of useful information with insight into how BT/EE is thinking about deploying 5G in UK.

Related Posts:

• Dr. Yue Wang: AI in 5G – the why and how - The 3G4G Blog
• CWHeritage Talk by Prof. Andy Sutton: The history of synchronisation in digital cellular networks - The 3G4G Blog
• Prof. Andy Sutton: 5G Network Architecture, Design and Optimisation - Jan 2018 - The 3G4G Blog
• 5G Network Architecture Options (Updated) - The 3G4G Blog
• 5G (IMT-2020) Wireless Resources - 3G4G Homepage

#CWHeritage Talk: The History of Synchronization in Digital Cellular Networks

CW (a.k.a. Cambridge Wireless) held a very interesting event titled 'Time for Telecoms' at the Science Museum in London. I managed to record this one talk by Prof. Andy Sutton, who has also kindly shared slides and some other papers that he mentions in his presentation. You can also see the tweets from the event on Twitter.

The video playlist and the presentation is embedded below.

The history of synchronisation in digital cellular networks from 3G4G

The papers referred to in the presentation/video available as follows:

• Martin Kingston: The need for Synchronisation in Telecommunications
• Charles Curry: Time from the Sky
• Sébastien Jobert & Kenneth Hann: Synchronisation and Time Distribution in Modern Telecommunications Networks
• Tommy Cook & Tim Frost: Stepping up to the Challenge on Tighter Time Accuracy.
• Andy Sutton: The history of synchronisation in digital cellular networks

5G Network Architecture, Design and Optimisation - Jan 2018

Prof. Andy Sutton, Principal Network Architect, Architecture & Strategy, TSO, BT, provided an update on 5G Network Architecture & Design last year which was also the most popular post of 2017 on 3G4G blog. This year again, he has delivered an update on the same topic at IET '5G - State of Play' conference. He has kindly shared the slides (embedded below) that are available to download from Slideshare.

5G Network Architecture, Design and Optimisation from 3G4G

The video of this talk as follows:


There are many valuable insights in this talk and the other talks from this conference. All the videos from the IET conference are available here and they are worth your time.

Related Links:

• [Video] The UK’s first end-to-end 5G network test - EE
• [Video] 5G Network Architecture Options - 3G4G
• [Video] Beginners: 5G Terminology - 3G4G
• 3GPP-VRIF workshop on Virtual Reality Ecosystem & Standards in 5G
• Ultra Reliable Low Latency Communications (URLLC) 2017 Conference summary

5G and CBRS Hype?

The dissenting voices on 5G and CBRS are getting louder. While there are many analysts & operators who have been cautioning against 5G, its still moving ahead with a rapid pace. In the recent Huawei Mobile Broadband forum for example, BT's boss admitted that making case for 5G is hard. Bruno Jacobfeuerborn, CTO of Deutsche Telekom on the other hand is sitting on the fence. Dean Bubley's LinkedIn post is interesting too.

Vodafone CTO asked yesterday: "Will 5G be like 2G and 4G, or like 3G?". Now, it's like 3G, designing use cases and apps that nobody knows if they will be successful (e.g. 3G video calling).
2G and 4G were all about letting users/developers create their own. #HWMBBF

— Dimitris Mavrakis (@dmavrakis) November 16, 2017

. @BJacobfeuerborn says the forthcoming glut of sporting events in Asia (three Olympics, winter and summer, in next five years) will give them a 5G headstart. "If you want to do massive infrastructure investment, you need events." #HWMBBF

— Mobile Europe (@mobileeurope) November 16, 2017

Anyway, we have storified most of the tweets from Huawei Mobile Broadband Forum here.

Signals Research Group recently published their Signals Flash report, which is different from the more detailed Signals Ahead reports looking at 5G and CBRS, in addition to other topics. I have embedded the report below (with permission - thanks Mike) but you can download your own copy from here.

The summary from their website will give a good idea of what that is about:

CBRS – Much Ado About Not Very Much.  The FCC is heading in the right direction with how it might regulate the spectrum. However, unless you are a WISP or a private entity looking to deploy a localized BWA service, we don’t see too many reasons to get excited.

Handicapping the 5G Race.  Millimeter wave networks will be geographically challenged, 600 MHz won’t scale or differentiate from LTE, Band 41 may be the most promising, but this isn’t saying much. Can network virtualization make a winner?

It makes no Cents! Contrary to widespread belief,  5G won’t be a new revenue opportunity for operators – at least in the near term. The vertical markets need to get on board while URLLC will lag eMBB and prove far more difficult to deploy.

This Fierce Wireless article summarises the issues with CBRS well.

“While (some) issues are being addressed, the FCC can’t solve how to carve up 150 MHz of spectrum between everyone that wants a piece of the pie, while also ensuring that everyone gets a sufficient amount of spectrum,” the market research firm said in a report. “The 150 MHz is already carved up into 7- MHz for PAL (Priority Access License) and 80 MHz for GAA (General Authorized Access). The pecking order for the spectrum is incumbents, followed by PAL, and then by GAA…. 40 MHz sounds like a lot of spectrum, but when it comes to 5G and eMBB, it is only somewhat interesting, in our opinion. Further, if there are multiple bidders going after the PAL licenses then even achieving 40 MHz could be challenging.”

Signals said that device compatibility will also be a significant speed bump for those looking to leverage CBRS. Manufacturers won’t invest heavily to build CBRS-compatible phones until operators deploy infrastructure “in a meaningful way,” but those operators will need handsets that support the spectrum for those network investments to pay dividends. So while CBRS should prove valuable for network operators, it may not hold as much value for those who don’t own wireless infrastructure.

“The device ecosystem will develop but it is likely the initial CBRS deployments will target the more mundane applications, like fixed wireless access and industrial IoT applications,” the firm said. “We believe infrastructure and devices will be able to span the entire range of frequencies—CBRS and C-Band—and the total amount of available spectrum, combined with the global interest in the C-Band for 5G services, will make CBRS more interesting and value to operators. Operators will just have to act now, and then wait patiently for everything to fall into place.”

While many parts of the world are focusing on using frequencies around and above 3.5GHz for 5G, USA would be the only country using it for 4G. I suspect that many popular devices may not support CBRS but could be good for Fixed Wireless Access (FWA). It remains to be seen if economy of scale would be achieved.

Signals Flash Nov 2017: 5G in Americas | Signals Research Group from 3G4G

A practical use of MOCN in ESN

Just came across this slide from recent DAS & Small Cells Congress where EE talked about their ESN network development. Found this particular example interesting as they talk about how the commercial user and ESN user would use the same RAN but a different core.

This ties nicely with a recent tutorial that I did on Mobile Network Sharing options. If you would like to learn more, see here.

Related Post (added 23 March 2019)

• Update on UK's Emergency Services Network (ESN) from BAPCO 2019

Different types of Mobile Masts

Today's post is inspired by two things. One of them being my most popular answer on Quora. As you can see, its gathered over 19K upvotes.

@MarcAlleraEE @ee #EEGoldenSIM killinghall mast? pic.twitter.com/eadBmZoJdd

— Sheree Barker (@SHEREEBEE) June 2, 2017

The other being #EEGoldenSIM competition started by Marc Allera, CEO of UK mobile operator, EE,. The users were required to find a mast, take a picture and share it. This led to a lot of people asking how do masts look like but also generated lots of interesting pictures. You can search #EEGoldenSIM on twitter to see them.

Below is a presentation prepared by my 3G4G colleagues on how different types of antennas and mobile masts look like. Hope you like it.

Antennas: A Collection from 3G4G

Theoretical calculation of EE's announcement for 429Mbps throughput

The CEO of UK mobile network operator EE recently announced on twitter that they have achieved 429 Mbps in live network. The following is from their press release:

EE, the UK’s largest mobile network operator and part of the BT Group, has switched on the next generation of its 4G+ network and demonstrated live download speeds of 429Mbps in Cardiff city centre using Sony’s Xperia XZ Premium, which launched on Friday 2 June. 

The state of the art network capability has been switched on in Cardiff and the Tech City area of London today. Birmingham, Manchester and Edinburgh city centres will have sites upgraded during 2017, and the capability will be built across central London. Peak speeds can be above 400Mbps with the right device, and customers connected to these sites should be able to consistently experience speeds above 50Mbps. 

Sony’s Xperia XZ Premium is the UK’s first ‘Cat 16’ smartphone optimised for the EE network, and EE is the only mobile network upgrading its sites to be able to support the new device’s unique upload and download capabilities. All devices on the EE network will benefit from the additional capacity and technology that EE is building into its network. 

... 

The sites that are capable of delivering these maximum speeds are equipped with 30MHz of 1800MHz spectrum, and 35MHz of 2.6GHz spectrum. The 1800MHz carriers are delivered using 4x4 MIMO, which sends and receives four signals instead of just two, making the spectrum up to twice as efficient. The sites also broadcast 4G using 256QAM, or Quadrature Amplitude Modulation, which increases the efficiency of the spectrum.

Before proceeding further you may want to check out my posts 'Gigabit LTE?' and 'New LTE UE Categories (Downlink & Uplink) in Release-13'

If you read the press release carefully, EE are now using 65MHz of spectrum for 4G. I wanted to provide a calculation for whats possible in theory with this much bandwidth.

Going back to basics (detailed calculation for basics in slideshare below), in LTE/LTE-A, the maximum bandwidth possible is 20MHz. Any more bandwidth can be used with Carrier Aggregation. So as per the EE announcement, its 20 + 10 MHz in 1800 band and 20 + 15 MHz in 2600 band

So for 1800 MHz band:

50 resource blocks (RBs) per 10MHZ, 150 for 30MHz.
Each RB has 12x7x2=168 symbols per millisecond in case of normal modulation support cyclic prefix (CP).
For 150 RBs, 150 x 168 = 25200 symbols per ms or 25,200,000 symbols per second. This can also be written as 25.2 Msps (Mega symbols per second)
256 QAM means 8 bits per symbol. So the calculation changes to 25.2 x 8 = 201.6 Mbps. Using 4 x 4 MIMO, 201.6 x 4 = 806.4Mbps
Removing 25% overhead which is used for signalling, this gives 604.80 Mbps


Repeating the same exercise for 35MHz of 2600 MHz band, with 2x2 MIMO and 256 QAM:

175 x 168 = 29400 symbols per ms or 29,400,000 symbols per second. This can be written as 29.4 Msps
29.4 x 8 = 235.2 Mbps
Using 2x2 MIMO, 235.2 x 2 = 470.4 Mbps
Removing 25% overhead which is used for signalling, this gives 352.80 Mbps

The combined theoretical throughput for above is 957.60 Mbps

For those interested in revisiting the basic LTE calculations, here is an interesting document:

Further reading:

• 5G SpeedTests and Theoretical Max Speeds Calculations
• LTE Peak Capacity Explained: How to Calculate it? - Frank Rayal
• Gigabit LTE?
• New LTE UE Categories (Downlink & Uplink) in Release-13

Connecting Rural Scotland using Airmasts and Droneways

This week EE has finally done a press release on what they term as Airmasts (see my blog post here). Back in Nov. last year, Mansoor Hanif, Director of Converged Networks and Innovation BT/EE gave an excellent presentation on connecting rural Scottish Islands using Airmasts and Droneways at the Facebook TIP Summit. Embedded below are the slides and video from that talk.

Driving Connectivity in the Scottish Islands: Droneways and Airmasts from 3G4G

In other related news, AT&T is showing flying COWs (Cell On Wheels) that can transmit LTE signals

Their innovation blog says:

It is designed to beam LTE coverage from the sky to customers on the ground during disasters or big events.
...
Here’s how it works. The drone we tested carries a small cell and antennas. It’s connected to the ground by a thin tether. The tether between the drone and the ground provides a highly secure data connection via fiber and supplies power to the Flying COW, which allows for unlimited flight time.  The Flying COW then uses satellite to transport texts, calls, and data. The Flying COW can operate in extremely remote areas and where wired or wireless infrastructure is not immediately available. Like any drone that we deploy, pilots will monitor and operate the device during use.

Once airborne, the Flying COW provides LTE coverage from the sky to a designated area on the ground.  

Compared to a traditional COW, in certain circumstances, a Flying COW can be easier to deploy due to its small size. We expect it to provide coverage to a larger footprint because it can potentially fly at altitudes over 300 feet— about 500% higher than a traditional COW mast.  

Once operational, the Flying COW could eventually provide coverage to an area up to 40 square miles—about the size of a 100 football fields. We may also deploy multiple Flying COWs to expand the coverage footprint.

Nokia on the other hand has also been showcasing drones and LTE connectivity for public safety at D4G Award event in Dubai

Nokia's Ultra Compact Network provides a standalone LTE network to quickly re-establish connectivity to various mission-critical applications including video-equipped drones. Drones can stream video and other sensor data in real time from the disaster site to a control center, providing inputs such as exact locations where people are stranded and nature of the difficulty of reaching the locations.

Related Posts:

• Flying Small Cells are here...
• Facebook's Attempt to Connect the Unconnected
• An Update from the TIP Summit
• Drone cells are becoming a reality
• When COWs Fly: AT&T Sending LTE Signals from Drones
• Nokia demos drones with LTE connection to conduct rescue operations