,1
Drivers for 5G: The ‘Pervasive Connected World’
Firooz B. Saghezchi,1 Jonathan Rodriguez,1 Shahid Mumtaz,1 Ayman Radwan,1 William C. Y.
Lee,2 Bo Ai,3 Mohammad Tauhidul Islam,4 Selim Akl4 and Abd-Elhamid M. Taha5
1 Instituto de Telecomunicações, Aveiro, Portugal
2 School of Advanced Communications, Peking University, China
3 State Key Laboratory of Rail Traffic Control and Safety, Beijing, China
4 School of Computing, Queen’s University, Kingston, Ontario, Canada
5 College of Engineering, Alfaisal University, Riyadh, KSA
1.1 Introduction
We have been witnessing an exponential growth in the amount of traffic carried through mobile
networks. According to the Cisco visual networking index [1], mobile data traffic has doubled
during 2010–2011; extrapolating this trend for the rest of the decade shows that global mobile
traffic will increase 1000x from 2010 to 2020.
The surge in mobile traffic is primarily driven by the proliferation of mobile devices and the
accelerated adoption of data-hungry mobile devices – especially smart phones. Table
1.1 provides a list of these devices along with their relative data consumptions. In addition to the
increasing adoption rate of these high-end mobile devices, the other important factor associated
with the tremendous mobile traffic growth is the increasing demand for advanced multi-media
applications such as Ultra-High Definition (UHD) and 3D video as well as augmented reality and
immersive experience. Today, mobile video accounts for more than 50% of global mobile data
traffic, which is anticipated to rise to two-thirds by 2018 [1]. Finally, social networking has
become important for mobile users, introducing new consumption behaviour and a considerable
amount of mobile data traffic.
Table 1.1 Data consumption of different mobile terminals.
Device Relative data usage
Feature phone 1x
Smart phone 24x
Handheld gaming console 60x
Tablet 122x
Laptop 515x
The growth rate of mobile data traffic is much higher than the voice counterpart. Global mobile
voice traffic was overtaken by mobile data traffic in 2009, and it is forecast that Voice over IP
(VoIP) traffic will represent only 0.4% of all mobile data traffic by 2015. In 2013, the number of
mobile subscriptions reached 6.8 billion, corresponding to a global penetration of 96%. The
ever-growing global subscriber rate spurred on by the world population growth will place
stringent new demands on potential 5G networks to cater for one billion new customers.
,Apart from 1000x traffic growth, the increasing number of connected devices imposes another
challenge on the future mobile network. It is envisaged that in the future connected society,
everyone and everything will be inter-connected – under the umbrella of Internet of Everything
(IoE) – where tens to hundreds of devices will serve every person. This upcoming 5G cellular
infrastructure and its support for Big Data will enable cities to be smart. Data will be generated
everywhere by both people and machines, and will be analysed in a real-time fashion to infer
useful information, from people’s habits and preferences to the traffic condition on the streets,
and health monitoring for patients and elderly people. Mobile communications will play a pivotal
role in enabling efficient and safe transportation by allowing vehicles to communicate with each
other or with a roadside infrastructure to warn or even help the drivers in case of unseen
hazards, paving the way towards autonomous self-driving cars. This type of machine-to-machine
(M2M) communications requires very stringent latency (less than 1 ms), which imposes further
challenges on the future network.
The 1000x mobile traffic growth along with trillions of connected devices is pushing the cellular
system to a broadband ubiquitous network with extreme capacity and Energy Efficiency (EE)
and diverse Quality of Service (QoS) support. Indeed, it is envisaged that the next-generation
cellular system will be the first instance of a truly converged wired and wireless network,
providing fibre-like experience for mobile users. This ubiquitous, ultra-broadband, and ultra-low
latency wireless infrastructure will connect the society and drive the future economy.
1.2 Historical Trend of Wireless Communications
A new generation of cellular system appears every 10 years or so, with the latest generation (4G)
being introduced in 2011. Following this trend, the 5G cellular system is expected to be
standardised and deployed by the early 2020s. The standardisation of the new air interfaces for
5G is expected to gain momentum after the International Telecommunication Union-
Radiocommunication Sector’s (ITU-R) meeting at the next World Radiocommunication
Conference (WRC), to be held in 2015. Table 1.2 summarises the rollout year as well as the
International Mobile Telecommunications (IMT) requirements for the peak and the average data
rates for different generations of the cellular system. Although IMT requirements for 5G are yet
to be defined, the common consensus from academic researchers and industry is that in principle
it should deliver a fibre-like mobile Internet experience with peak rates of up to 10 Gbps in
static/low mobility conditions, and 1 Gbps blanket coverage for highly mobile/cell edge users
(with speeds of > 300 km/h). The round-trip time latency of the state-of-the-art 4G system
(Long-Term Evolution – Advanced; LTE-A) is around 20 ms, which is expected to diminish to less
than 1 ms for 5G.
Table 1.2 Specifications of different generations of cellular systems.
IMT requirement for data rate
Generation Rollout Mobile users Stationary users
year
1G 1981 – –
2G 1992 – –
3G 2001 384 Kbps >2 Mbps
, IMT requirement for data rate
Generation Rollout Mobile users Stationary users
year
4G 2011 100 Mbps 1 Gbps
5G 2021 1 Gbps 10 Gbps
Global standards are a fundamental cornerstone in reaching ubiquitous connectivity, ensuring
worldwide interoperability, enabling multi-vendor harmonisation and economies of scale. ITU-
R is responsible for defining IMT specifications for next-generation cellular systems. Having
defined two previous specifications (IMT-2000 for 3G and IMT-Advanced for 4G), it has already
commenced activities towards defining specifications for 5G, which is aimed for completion
around 2015. ITU-R arranges WRCs every three to four years to review and revise radio
regulations. Allocation of new spectrum for mobile communications is already on the agenda of
the next WRC, to be held in November 2015.
To understand where we want to be in terms of 5G, it is worthwhile to appreciate where it all
started and to mark where we are now. The following provides a roadmap of the evolution
towards 5G communications:
Before 1G (<1983): All the wireless communications were voice-centric and used
analogue systems with single-side-band (SSB) modulation.
1G (1983–): All the wireless communications were voice-centric. In 1966, Bell Labs had
made a decision to adopt analogue systems for a high-capacity mobile system, because at
that time the digital radio systems were very expensive to manufacture. An analogue
system with FM radios was chosen. In 1983, the US cellular system was named AMPS
(Advanced Mobile Phone Service). AMPS was called 1G at the time.
2G (1990–): During this period, all the wireless communications were voice-centric.
European GSM and North America IS-54 were digital systems using TDMA multiplexing.
Since AT&T was divested in 1980, no research institute like Bell Labs could develop an
outstanding 2G system as it did for the 1G system in North America. IS-54 was not a
desirable system and was abandoned. Then, GSM was named 2G at the time when 3G was
defined by ITU in 1997. Thus, we could say that moving from 1G to 2G means migrating
from the analogue system to the digital system.
2.5G (1995–): All the wireless communications are mainly for high-capacity voice with
limited data service. The CDMA (code division multiple access) system using 1.25 MHz
bandwidth was adopted in the United States. At the same time, European countries
enhanced GSM to GPRS and EDGE systems.
3G (1999–): In this generation, the wireless communications platform has voice and data
capability. 3G is the first international standard system released from ITU, in contrast to
previous generation systems. 3G exploits WCDMA (Wideband Code Division
Multiple Access) technology using 5 MHz bandwidth. It operates in both frequency
division duplex (FDD) and time division duplex (TDD) modes. Thus, we could say that by
migrating from 2G to 3G systems we have evolved from voice-centric systems to data-
centric systems.
Drivers for 5G: The ‘Pervasive Connected World’
Firooz B. Saghezchi,1 Jonathan Rodriguez,1 Shahid Mumtaz,1 Ayman Radwan,1 William C. Y.
Lee,2 Bo Ai,3 Mohammad Tauhidul Islam,4 Selim Akl4 and Abd-Elhamid M. Taha5
1 Instituto de Telecomunicações, Aveiro, Portugal
2 School of Advanced Communications, Peking University, China
3 State Key Laboratory of Rail Traffic Control and Safety, Beijing, China
4 School of Computing, Queen’s University, Kingston, Ontario, Canada
5 College of Engineering, Alfaisal University, Riyadh, KSA
1.1 Introduction
We have been witnessing an exponential growth in the amount of traffic carried through mobile
networks. According to the Cisco visual networking index [1], mobile data traffic has doubled
during 2010–2011; extrapolating this trend for the rest of the decade shows that global mobile
traffic will increase 1000x from 2010 to 2020.
The surge in mobile traffic is primarily driven by the proliferation of mobile devices and the
accelerated adoption of data-hungry mobile devices – especially smart phones. Table
1.1 provides a list of these devices along with their relative data consumptions. In addition to the
increasing adoption rate of these high-end mobile devices, the other important factor associated
with the tremendous mobile traffic growth is the increasing demand for advanced multi-media
applications such as Ultra-High Definition (UHD) and 3D video as well as augmented reality and
immersive experience. Today, mobile video accounts for more than 50% of global mobile data
traffic, which is anticipated to rise to two-thirds by 2018 [1]. Finally, social networking has
become important for mobile users, introducing new consumption behaviour and a considerable
amount of mobile data traffic.
Table 1.1 Data consumption of different mobile terminals.
Device Relative data usage
Feature phone 1x
Smart phone 24x
Handheld gaming console 60x
Tablet 122x
Laptop 515x
The growth rate of mobile data traffic is much higher than the voice counterpart. Global mobile
voice traffic was overtaken by mobile data traffic in 2009, and it is forecast that Voice over IP
(VoIP) traffic will represent only 0.4% of all mobile data traffic by 2015. In 2013, the number of
mobile subscriptions reached 6.8 billion, corresponding to a global penetration of 96%. The
ever-growing global subscriber rate spurred on by the world population growth will place
stringent new demands on potential 5G networks to cater for one billion new customers.
,Apart from 1000x traffic growth, the increasing number of connected devices imposes another
challenge on the future mobile network. It is envisaged that in the future connected society,
everyone and everything will be inter-connected – under the umbrella of Internet of Everything
(IoE) – where tens to hundreds of devices will serve every person. This upcoming 5G cellular
infrastructure and its support for Big Data will enable cities to be smart. Data will be generated
everywhere by both people and machines, and will be analysed in a real-time fashion to infer
useful information, from people’s habits and preferences to the traffic condition on the streets,
and health monitoring for patients and elderly people. Mobile communications will play a pivotal
role in enabling efficient and safe transportation by allowing vehicles to communicate with each
other or with a roadside infrastructure to warn or even help the drivers in case of unseen
hazards, paving the way towards autonomous self-driving cars. This type of machine-to-machine
(M2M) communications requires very stringent latency (less than 1 ms), which imposes further
challenges on the future network.
The 1000x mobile traffic growth along with trillions of connected devices is pushing the cellular
system to a broadband ubiquitous network with extreme capacity and Energy Efficiency (EE)
and diverse Quality of Service (QoS) support. Indeed, it is envisaged that the next-generation
cellular system will be the first instance of a truly converged wired and wireless network,
providing fibre-like experience for mobile users. This ubiquitous, ultra-broadband, and ultra-low
latency wireless infrastructure will connect the society and drive the future economy.
1.2 Historical Trend of Wireless Communications
A new generation of cellular system appears every 10 years or so, with the latest generation (4G)
being introduced in 2011. Following this trend, the 5G cellular system is expected to be
standardised and deployed by the early 2020s. The standardisation of the new air interfaces for
5G is expected to gain momentum after the International Telecommunication Union-
Radiocommunication Sector’s (ITU-R) meeting at the next World Radiocommunication
Conference (WRC), to be held in 2015. Table 1.2 summarises the rollout year as well as the
International Mobile Telecommunications (IMT) requirements for the peak and the average data
rates for different generations of the cellular system. Although IMT requirements for 5G are yet
to be defined, the common consensus from academic researchers and industry is that in principle
it should deliver a fibre-like mobile Internet experience with peak rates of up to 10 Gbps in
static/low mobility conditions, and 1 Gbps blanket coverage for highly mobile/cell edge users
(with speeds of > 300 km/h). The round-trip time latency of the state-of-the-art 4G system
(Long-Term Evolution – Advanced; LTE-A) is around 20 ms, which is expected to diminish to less
than 1 ms for 5G.
Table 1.2 Specifications of different generations of cellular systems.
IMT requirement for data rate
Generation Rollout Mobile users Stationary users
year
1G 1981 – –
2G 1992 – –
3G 2001 384 Kbps >2 Mbps
, IMT requirement for data rate
Generation Rollout Mobile users Stationary users
year
4G 2011 100 Mbps 1 Gbps
5G 2021 1 Gbps 10 Gbps
Global standards are a fundamental cornerstone in reaching ubiquitous connectivity, ensuring
worldwide interoperability, enabling multi-vendor harmonisation and economies of scale. ITU-
R is responsible for defining IMT specifications for next-generation cellular systems. Having
defined two previous specifications (IMT-2000 for 3G and IMT-Advanced for 4G), it has already
commenced activities towards defining specifications for 5G, which is aimed for completion
around 2015. ITU-R arranges WRCs every three to four years to review and revise radio
regulations. Allocation of new spectrum for mobile communications is already on the agenda of
the next WRC, to be held in November 2015.
To understand where we want to be in terms of 5G, it is worthwhile to appreciate where it all
started and to mark where we are now. The following provides a roadmap of the evolution
towards 5G communications:
Before 1G (<1983): All the wireless communications were voice-centric and used
analogue systems with single-side-band (SSB) modulation.
1G (1983–): All the wireless communications were voice-centric. In 1966, Bell Labs had
made a decision to adopt analogue systems for a high-capacity mobile system, because at
that time the digital radio systems were very expensive to manufacture. An analogue
system with FM radios was chosen. In 1983, the US cellular system was named AMPS
(Advanced Mobile Phone Service). AMPS was called 1G at the time.
2G (1990–): During this period, all the wireless communications were voice-centric.
European GSM and North America IS-54 were digital systems using TDMA multiplexing.
Since AT&T was divested in 1980, no research institute like Bell Labs could develop an
outstanding 2G system as it did for the 1G system in North America. IS-54 was not a
desirable system and was abandoned. Then, GSM was named 2G at the time when 3G was
defined by ITU in 1997. Thus, we could say that moving from 1G to 2G means migrating
from the analogue system to the digital system.
2.5G (1995–): All the wireless communications are mainly for high-capacity voice with
limited data service. The CDMA (code division multiple access) system using 1.25 MHz
bandwidth was adopted in the United States. At the same time, European countries
enhanced GSM to GPRS and EDGE systems.
3G (1999–): In this generation, the wireless communications platform has voice and data
capability. 3G is the first international standard system released from ITU, in contrast to
previous generation systems. 3G exploits WCDMA (Wideband Code Division
Multiple Access) technology using 5 MHz bandwidth. It operates in both frequency
division duplex (FDD) and time division duplex (TDD) modes. Thus, we could say that by
migrating from 2G to 3G systems we have evolved from voice-centric systems to data-
centric systems.
