essay about 5g technology

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Essay On 5g Technology: Free Samples Available for Students

• Updated on  
• Dec 29, 2023

Congratulations to the world on the evolution of technology; from the first general-public computer named INIAC in 1945 to 5g technology in 2022, technology has greatly improved and has eased our lives. 5g technology is the advanced version of the 4g LTE (Long Term Evolution) mobile broadband service. We have all grown up from traditional mobile top-ups to digital recharges. According to sources, 5g is 10 times faster than 4g; a 4g connection has a download speed of 1 GBPS (Gigabyte Per Sec) and 5g has 10 GBPS. Below we have highlighted some sample essay on 5g technology.

Table of Contents

• 1 Essay on 5G Technology in 250 words
• 2.0.1 Conclusion
• 3 Benefits of 5G
• 4 10 Lines to Add to Your Essay on Technology

Also Read: Short Speech on Technology for School Students Short Essay on 5g Technology

The fifth generation or 5g technology for mobile networks was deployed all over the world in 2019, with South Korea becoming the first country to adopt it on a large scale. In mobile or cellular networks, the service or operating areas are divided into geographical units termed cells. The radio waves connect all the 5g mobile devices in a cell with the telephone network and the Internet. 

5g is 10 times faster than its predecessor, 4g, and can connect more devices in a particular area. Not only this, it also introduces new technologies such as Massive MIMO (Multiple Input, Multiple Output), beamforming, and network slicing. Before switching to 5g, make sure to remember that 5g is not compatible with 4g devices.

Also Read: Essay on Health and Fitness for Students

Essay on 5G Technology in 250 words

The fifth generation of networks is the 5G network and this network promises to bring faster internet speed, lower latency, and improved reliability to mobile devices. In India, it is expected to have a significant impact on several industries such as healthcare, education, agriculture, entertainment, etc.

5G carries a lot of features such as:-

• Higher speeds: – The 5G network will have wider bandwidth which will allow for more data to flow. Hence, it will result in higher download and upload speeds.
• More capacity :- 5G network, in comparison to 4G, will have greater capacity to hold more network devices. This is very essential as the number of network devices increases each day.
• Lower latency: – 5G network will have much lower latency. This is essential for many tasks such as video conferencing or even online gaming which is a known profession these days. 

Due to all these, a lot of things will have a positive impact. Connectivity will improve and enable even the most rural areas to become connected to the rest of the world. 5G technology will help revolutionise the healthcare industry in India in ways such as telemedicine, remote surgeries, real-time patient monitoring, etc. 

However, like any other innovation, 5G does come with some concerns. There are certain concerns regarding the security of the 5G network, hence Indian Government needs to ensure that this network is safe from all the cyber threats. Also, although not proven, there are some concerns regarding the effects of 5G radiation on health. 

There is no doubt that 5G technology holds immense potential for India. And although there are many challenges to its deployment, the Indian Government and other industry experts should work together to over come these challenges and make the most of this technology.

350 Word Essay on 5g Technology

How significantly technology has improved. 50 years back nobody would have imagined that a mobile connection would allow us to connect anywhere in the world. With 5g technology, we can connect virtually anywhere with anyone in real-time. This advanced broadband connection offers us a higher internet speed, which can reach up to two-digit gigabits per second (Gbps). This increase in internet speed is achieved through the use of higher-frequency radio waves and advanced technologies.

The world of telecommunication is evolving at a very fast pace. 3g connectivity was adopted in 2003, 4g in 2009, and 5g in 2019. the advent of 5G technology represents an enormous leap forward, promising to reshape the way we connect, communicate, and interact with the digital world. 

The 5th Generation of mobile networks stands out from its predecessors in speed, latency, and the capacity to support a larger array of devices and applications. 5g speed is one of the most remarkable features, which allows us to download large amounts of files from the internet in mere seconds. Not only this, it also allows us smoother streaming of HD content and opens the door to transformative technologies.  Augmented reality (AR) and virtual reality (VR) experiences, which demand substantial data transfer rates, will become more immersive and accessible with 5G.

What is the difference between 5g and 4g?

The difference between 5g and 4g technologies clearly highlighted in their speed, latency, frequency bands, capacity and multiple other uses.

• The average downloading speed of 4g connectivity was 5 to 1000 Mbps (megabytes per sec). But with 5g, this speed increases 10 times.
• 4G networks had a latency of around 30-50 milliseconds and 5g reduces latency to as low as 1 millisecond or even less.
• 4G networks mainly use lower frequency bands below 6 GHz, but,  5g utilizes a broader range of frequencies, including lower bands (sub-6 GHz) and higher bands (millimeter waves or mmWave).
• 4g was well-suited for broadband applications like web browsing, video streaming, and voice calls. 5g is capable of supporting a large number of applications from smart cities, critical communication services, and applications that demand ultra-reliable low-latency communication.

Benefits of 5G

• Lower Latency: 5G Network will have extremely lower latency compared to that of 4G LTE. This will result in a much more smoother experience in terms of real time communication such as video conferencing or online gaming.
• Faster Speeds : 5G Network is expected to peak at high speeds of around 10 Gbps which is extremely high as compared to that of 4G LTE. This will result in high download as well as upload speeds and much smoother video streaming, etc.
• New Applications: Some applications that were not possible with 4G LTE will now be possible because of 5G such as remote surgery, augmented reality, etc.
• More Capacity: 5G bands can support Much more devices as compared to 4G LTE networks. This is extremely important as the number of connected grows everyday.

Also Read: Essay on Farmer for School Students

10 Lines to Add to Your Essay on Technology

Here are 10 simple and easy quotes on 5g technology. You can add them to your essay on 5g technology or any related writing topic to impress your readers.

• 5g technology is the fifth generation of mobile or cellular networks.
• 5g offers significantly higher download speeds, reaching several gigabits per second.
• 5g technology’s ultra-low latency is one of the most striking features, which can reduce delays to as little as 1 millisecond.
• 5G utilizes a diverse spectrum, including both lower bands (sub-6 GHz) and higher bands (mmWave).
• The increased speed and low latency of 5G support emerging technologies like augmented reality (AR) and virtual reality (VR).
• It enables a massive Internet of Things (IoT) ecosystem, connecting a vast number of devices simultaneously.
• 5G is essential for applications requiring real-time responsiveness, such as autonomous vehicles and remote surgery.
• The deployment of 5G networks is underway globally, transforming how we connect and communicate.
• Smart cities leverage 5G to enhance efficiency through interconnected systems and sensors.
• As the backbone of the digital era, 5G technology is driving innovation and shaping the future of connectivity.

Related Articles

Ans: 5g technology is the advanced generation of the 4g technology. It’s a mobile broadband service, which allows users to have faster access to the internet. Our everyday tasks on the internet will be greatly improved using 5g technology. 5g is 10 times faster than its predecessor, 4g and can connect more devices in a particular area. Not only this, it also introduces new technologies such as Massive MIMO (Multiple Input, Multiple Output), beamforming, and network slicing. Before switching to 5g, make sure to remember that 5g is not compatible with 4g devices.

Ans: 4g technology has a download speed of 5 to 10 Gbps. This broadband service is 10 times faster than its predecessor, 4g.

Ans: 5g is an advanced version of the 4g connectivity in terms of speed, latency, frequency bands, capability, and uses. 4G networks had a latency of around 30-50 milliseconds and 5g reduces latency to as low as 1 millisecond or even less.

For more information on such interesting topics to help you with your school, visit our essay writing page and follow Leverage Edu .

Shiva Tyagi

With an experience of over a year, I've developed a passion for writing blogs on wide range of topics. I am mostly inspired from topics related to social and environmental fields, where you come up with a positive outcome.

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What is 5G?

Fifth time’s the charm: 5G—or fifth-generation wireless technology— is powering the Fourth Industrial Revolution . Sure, 5G is faster than 4G. But 5G is more than just (a lot) faster: the connectivity made possible with 5G is significantly more secure and more stable than its predecessors. Plus, 5G enables data to travel from one place to another with a significantly shorter delay between data submission and arrival—this delay is known as latency.

Here are a few big numbers from the International Telecommunications Union . 5G networks aim to deliver:

• 1,000 times higher mobile data volume per area
• 100 times the number of connected devices
• 100 times higher user data rate
• ten times longer battery life for low-power massive-machine communications
• five times reduced end-to-end latency

Here’s how it works: like all cellular networks, the service area of 5G networks is divided into geographic sub-areas called cells. Each cell has local antennae, through which all wireless devices in the cell are connected to the internet and telephone network via radio waves. To achieve its very high speeds, 5G utilizes low- and midbands on the radio spectrum  (below six gigahertz), as well as whole new bands of the radio spectrum . These are so-called “millimeter waves,” broadcast at frequencies between 30 and 300 gigahertz, which have previously been used only for communication between satellites and radar systems.

Cell phone companies began deploying 5G in 2019. In the United States, 5G coverage is already available in many areas . And, while previous generation 2G and 3G technology is still in use, 5G adoption is accelerating: according to various predictions, 5G networks will have billions of subscribers by 2025.

But 5G can do more than enable faster loading of cat videos. This new speed and responsiveness—and the connectivity solutions it makes possible—is poised to transform a wide variety of industries.

Learn more about our Technology, Media & Telecommunications Practice .

How will 5G be used?

To date, 5G will enable four key use-case archetypes , which will require 5G to deliver on its promise of evolutionary change in network performance. They are:

• Enhanced mobile broadband . The faster speed, lower latency, and greater capacity 5G makes possible could enable on-the-go, ultra-high-definition video, virtual reality, and other advanced applications.
• Internet of Things (IoT) . Existing cellular networks are not able to keep up with the explosive growth in the number of connected devices, from smart refrigerators to devices monitoring battery levels on manufacturing shop floors. 5G will unlock the potential of IoT by enabling exponentially more connections at very low power.
• Mission-critical control . Connected devices are increasingly used in applications that require absolute reliability, such as vehicle safety systems or medical devices. 5G’s lower latency and higher resiliency mean that these time-critical applications will be increasingly reliable.
• Fixed wireless access . The speeds made possible by 5G make it a viable alternative to wired broadband in many markets, particularly those without fiber optics.

How might 5G and other advanced technologies impact the world?

If 5G is deployed across just four commercial domains—mobility, healthcare, manufacturing, and retail—it could boost global GDP by up to $2 trillion by 2030. Most of this value will be captured with creative applications of advanced connectivity.

Here are the four commercial domains with some of the largest potential to capture higher revenues or cost efficiencies:

• Connectivity will be the foundation for increasingly intelligent mobility systems, including carsharing services, public transit, infrastructure, hardware and software, and more. Connectivity could create new revenue streams through preventive maintenance, improved navigation and carpooling services, and personalized “infotainment” offerings.
• Devices and advanced networks with improved connectivity could transform the healthcare industry. Seamless data flow and low-latency networks could mean better robotic surgery. AI-powered decision support tools can make faster and more accurate diagnoses, as well as automate tasks so that caregivers can spend more time with patients. McKinsey analysis estimates that these use cases together could generate up to $420 billion in global GDP impact by 2030 .
• Low-latency and private 5G networks can power highly precise operations in manufacturing and other advanced industries . Smart factories powered by AI , analytics, and advanced robotics can run at maximum efficiency, optimizing and adjusting processes in real time. New features like automated guided vehicles and computer-vision-enhanced bin picking and quality control require the kind of speed and latency provided by high-band 5G. By 2030, the GDP impact in manufacturing could reach up to $650 billion .
• Retailers can use technology like sensors, trackers, and computer vision to manage inventories, improve warehouse operations, and coordinate along the supply chain. Use cases like connectivity-enhanced in-store experiences and real-time personalized recommendations could boost global GDP up to $700 billion by 2030 .

The use cases identified in these commercial domains alone could boost global GDP by up to $2 trillion by 2030 . The value at stake could ultimately run trillions of dollars higher across the entire global economy.

Beyond industry, 5G connectivity has important implications for society. Enabling more people to plug into global flows of information, communication, and services could add another $1.5 trillion to $2 trillion to GDP . This stands to unlock greater human potential and prosperity, particularly in developing nations .

Learn more about our Technology, Media & Telecommunications  Practice.

What are advanced connectivity and frontier connectivity?

Advanced connectivity is propelled by the continued evolution  of existing connectivity technologies, as networks are built out and adoption grows. For instance, providers are upgrading existing 4G infrastructure with 5G network overlays, which generally offer improvements in speed and latency while supporting a greater density of connected devices. At the same time, land-based fiber optic networks continue to expand, enabling faster data connections all over the world.

Introducing McKinsey Explainers : Direct answers to complex questions

On the other hand, frontier technologies like millimeter-wave 5G and low-earth-orbit satellite constellations offer a more radical leap forward . Millimeter-wave 5G is the ultra-fast mobile option, but comes with significant deployment challenges. Low-earth-orbit (LEO) satellites could deliver a breakthrough in breadth of coverage. LEO satellites work by beaming broadband down from space, bringing coverage to remote parts of the world where physical internet infrastructure doesn’t make sense for a variety of reasons. Despite the promise of LEO technology, challenges do remain, and no commercial services are yet available.

How are telecommunications players grappling with the transition to 5G?

5G promises better connectivity for consumers and organizations. Network providers, on the other hand, are resigned  to higher costs to deploy 5G infrastructure before they can reap the benefits. This cycle has happened before: with the advent of 4G, telcos in Europe and Latin America reported decreased revenues.

Given these realities, telecommunications players are working to develop their 5G investment strategies . In order to achieve the speed, latency, and reliability required by most advanced applications, network providers will need to invest in all network domains, including spectrum, radio access network infrastructure, transmission, and core networks. More specifically, operators will increasingly share more parts of the network, including towers, backhaul, and even spectrum and radio access, through so-called MOCN (Multi-Operator Core Network) or MORAN (Multi-Operator Radio Access Network) deals. This is a 5G-specific way for operators to cope with higher investment burdens at flat revenues.

Some good news: 5G technology is largely built on 4G networks, which means that mobile operators can simply evolve their infrastructure investment  rather than start from scratch. For instance, operators could begin by upgrading the capacity of their existing 4G network by refarming a portion of their 2G and 3G spectrum, thereby delaying investments in 5G. This would allow operators to minimize investments while the revenue potential of 5G remains uncertain.

How will telecommunications players monetize 5G in the B2C market?

The rise of 5G also presents an opportunity for telecommunications players to shift their customer engagement. As they reckon with the costs of 5G, they also must reimagine how to charge customers for 5G . The B2B 5G revolution is already under way; in the B2C market, the value proposition of 5G is less clear. That’s because there is no 5G use case compelling enough, at the present time, to transform the lives of people not heavily invested in gaming, for instance.

But despite the uncertainty, McKinsey has charted a clear path  for telecommunications organizations to monetize 5G in the B2C sector. There are three models telcos might pursue, which could increase average revenue per user by up to 20 percent:

• Impulse purchases and “business class” plans . 5G technology will allow telcos to move away from standard monthly subscriptions toward flexible plans that allow for customers to upgrade network performance when and where they feel the urge. Business class plans could feature premium network conditions at all times. According to McKinsey analysis, 7 percent of customers  are already ready to use 5G boosters, and would use them an average of seven times per month if each boost cost $1.
• Selling 5G-enabled experiences . The speeds and latency of 5G make possible streamlined and seamless experiences such as multiplayer cloud gaming, real-time translation, and augmented reality (AR) sports streaming. McKinsey research shows that customers are willing to pay  for these 5G-enabled experiential use cases, and more.
• Using partnerships to deliver 5G-enabled experiences . When assessing customer willingness to pay for 5G cloud gaming, McKinsey analysis showed that 74 percent of customers  would prefer buying a 5G service straight from the game app rather than from their mobile provider. To create a seamless experience for customers, telcos could embed 5G connectivity directly into their partners’ apps or devices. This could greatly expand telecommunications organizations’ customer base.

How has COVID-19 impacted connectivity IoT?

For one thing, the pandemic has created the need for applications with the advanced connectivity that only 5G can provide. Among other things, 5G enables the types of applications that help leaders understand whether their workforces are safe and which devices have been connected to the network and by whom.

Advanced connectivity technologies like 5G also stand to enable remote healthcare , although, ironically, the pandemic has also eaten up the resources necessary to create the infrastructure to implement it.

During the pandemic, Industry 4.0 frontrunners have done very well. This illustrates the fact that digital first businesses are nimbler and better prepared to react to unforeseen challenges.

Learn more about our Healthcare Systems & Services  Practice.

How can advanced electronics companies and industrials benefit from 5G?

The 5G Internet of Things (IoT)  B2B market, and its development over the coming years, offer significant opportunities for advanced electronics organizations. 5G IoT refers to industrial use-case archetypes enabled by the faster, more stable, and more secure connectivity available with 5G. McKinsey analyzed the events surrounding the introduction of 4G and other technologies, looking for clues about how 5G might evolve in the industry.

We found that many companies will derive great value from 5G IoT, but it will come in waves . The first 5G IoT use-case archetypes to gain traction will be those related to enhanced mobile broadband, followed shortly thereafter by use cases for ultra-reliable, low-latency communication. Finally, use cases for massive machine-type communication will take several more years. The businesses best placed to benefit from the growth of 5G include mobile operators, network providers, manufacturing companies, and machinery and industrial automation companies.

The B2B sector is especially well placed to benefit from 5G IoT. The most relevant short-term opportunities for 5G IoT involve Industry 4.0 , or the digitization of manufacturing and other production processes. The Industry 4.0 segment will account for sales of about 22 million 5G IoT units by 2030, with most applications related to manufacturing.

In order to take advantage of the opportunity, advanced electronics companies should look now to revamping their strategies . In the short-term, they should focus on B2B cases that are similar to those now being deployed in the B2C sector. Looking ahead, they should shift their focus toward developing hardware and software tailored to specific applications. But expanding the business field is always something that should be done with great care and consideration.

How will 5G impact the manufacturing industry?

There are five potential applications that are particularly relevant  for manufacturing organizations:

• Cloud control of machines . In the past, automation of machines in factories has relied on controllers that were physically installed on or near machines, which would then send information to computer networks. With 5G, this monitoring can in theory be done in the cloud, although these remain edge cases for now.
• Augmented reality . Seamless AR made possible by 5G connectivity will ultimately replace standard operating procedures currently on paper or video. These will help shop-floor workers undertake advanced tasks without waiting for specialists.
• Perceptive AI eyes on the factory floor . 5G will allow for live video analytics based on real-time video data streaming to the cloud.
• High-speed decisioning. The best-run factories rely on massive data lakes to make decisions. 5G accelerates the decision-cycle time, allowing massive amounts of data to be collected, cleaned, and analyzed in close to real time.
• Shop-floor IoTs . The addition of sensors to machines on factory floors means more data than ever before. The speeds made possible by 5G will allow for the operationalization of these new data.

Learn more about our Operations  Practice.

For a more in-depth exploration of these topics, see McKinsey’s Technology, Media & Telecommunications Practice. Also check out 5G-related job opportunities if you’re interested in working at McKinsey.

Articles referenced:

• “ Unlocking the value of 5G in the B2C marketplace ,” November 5, 2021, Ferry Grijpink , Jesper Larsson, Alexandre Ménard , and Konstantin Pell
• “ Connected world: An evolution in connectivity beyond the 5G revolution ,” February 20, 2020, Ferry Grijpink , Eric Kutcher , Alexandre Ménard , Sree Ramaswamy, Davide Schiavotto , James Manyika , Michael Chui , Rob Hamill, and Emir Okan
• The 5G era: New Horizons for advanced electronics in industrial companies , February 21, 2020, Ondrej Burkacky , Stephanie Lingemann, Alexander Hoffmann, and Markus Simon
• “ Five ways that 5G will revolutionize manufacturing ,” October 18, 2019, Enno de Boer , Sid Khanna , Andy Luse , Rahul Shahani , and Stephen Creasy
• “ Cutting through the 5G hype: Survey shows telcos’ nuanced views ,” February 13, 2019, Ferry Grijpink , Tobias Härlin, Harrison Lung, and Alexandre Ménard
• “ The road to 5G: The inevitable growth of infrastructure cost ,” February 23, 2018, Ferry Grijpink , Alexandre Ménard , Halldor Sigurdsson , and Nemanja Vucevic
• “ Are you ready for 5G? ,” February 22, 2018, Mark Collins, Arnab Das, Alexandre Ménard , and Dev Patel

Want to know more about 5G?

Related articles.

Connected world: An evolution in connectivity beyond the 5G revolution

Unlocking the value of 5G in the B2C marketplace

What is the Internet of Things?

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Study and Investigation on 5G Technology: A Systematic Review

Ramraj dangi.

1 School of Computing Science and Engineering, VIT University Bhopal, Bhopal 466114, India; [email protected] (R.D.); [email protected] (P.L.)

Praveen Lalwani

Gaurav choudhary.

2 Department of Applied Mathematics and Computer Science, Technical University of Denmark, 2800 Lyngby, Denmark; moc.liamg@7777yrahduohcvaruag

3 Department of Information Security Engineering, Soonchunhyang University, Asan-si 31538, Korea

Giovanni Pau

4 Faculty of Engineering and Architecture, Kore University of Enna, 94100 Enna, Italy; [email protected]

Associated Data

Not applicable.

In wireless communication, Fifth Generation (5G) Technology is a recent generation of mobile networks. In this paper, evaluations in the field of mobile communication technology are presented. In each evolution, multiple challenges were faced that were captured with the help of next-generation mobile networks. Among all the previously existing mobile networks, 5G provides a high-speed internet facility, anytime, anywhere, for everyone. 5G is slightly different due to its novel features such as interconnecting people, controlling devices, objects, and machines. 5G mobile system will bring diverse levels of performance and capability, which will serve as new user experiences and connect new enterprises. Therefore, it is essential to know where the enterprise can utilize the benefits of 5G. In this research article, it was observed that extensive research and analysis unfolds different aspects, namely, millimeter wave (mmWave), massive multiple-input and multiple-output (Massive-MIMO), small cell, mobile edge computing (MEC), beamforming, different antenna technology, etc. This article’s main aim is to highlight some of the most recent enhancements made towards the 5G mobile system and discuss its future research objectives.

1. Introduction

Most recently, in three decades, rapid growth was marked in the field of wireless communication concerning the transition of 1G to 4G [ 1 , 2 ]. The main motto behind this research was the requirements of high bandwidth and very low latency. 5G provides a high data rate, improved quality of service (QoS), low-latency, high coverage, high reliability, and economically affordable services. 5G delivers services categorized into three categories: (1) Extreme mobile broadband (eMBB). It is a nonstandalone architecture that offers high-speed internet connectivity, greater bandwidth, moderate latency, UltraHD streaming videos, virtual reality and augmented reality (AR/VR) media, and many more. (2) Massive machine type communication (eMTC), 3GPP releases it in its 13th specification. It provides long-range and broadband machine-type communication at a very cost-effective price with less power consumption. eMTC brings a high data rate service, low power, extended coverage via less device complexity through mobile carriers for IoT applications. (3) ultra-reliable low latency communication (URLLC) offers low-latency and ultra-high reliability, rich quality of service (QoS), which is not possible with traditional mobile network architecture. URLLC is designed for on-demand real-time interaction such as remote surgery, vehicle to vehicle (V2V) communication, industry 4.0, smart grids, intelligent transport system, etc. [ 3 ].

1.1. Evolution from 1G to 5G

First generation (1G): 1G cell phone was launched between the 1970s and 80s, based on analog technology, which works just like a landline phone. It suffers in various ways, such as poor battery life, voice quality, and dropped calls. In 1G, the maximum achievable speed was 2.4 Kbps.

Second Generation (2G): In 2G, the first digital system was offered in 1991, providing improved mobile voice communication over 1G. In addition, Code-Division Multiple Access (CDMA) and Global System for Mobile (GSM) concepts were also discussed. In 2G, the maximum achievable speed was 1 Mpbs.

Third Generation (3G): When technology ventured from 2G GSM frameworks into 3G universal mobile telecommunication system (UMTS) framework, users encountered higher system speed and quicker download speed making constant video calls. 3G was the first mobile broadband system that was formed to provide the voice with some multimedia. The technology behind 3G was high-speed packet access (HSPA/HSPA+). 3G used MIMO for multiplying the power of the wireless network, and it also used packet switching for fast data transmission.

Fourth Generation (4G): It is purely mobile broadband standard. In digital mobile communication, it was observed information rate that upgraded from 20 to 60 Mbps in 4G [ 4 ]. It works on LTE and WiMAX technologies, as well as provides wider bandwidth up to 100 Mhz. It was launched in 2010.

Fourth Generation LTE-A (4.5G): It is an advanced version of standard 4G LTE. LTE-A uses MIMO technology to combine multiple antennas for both transmitters as well as a receiver. Using MIMO, multiple signals and multiple antennas can work simultaneously, making LTE-A three times faster than standard 4G. LTE-A offered an improved system limit, decreased deferral in the application server, access triple traffic (Data, Voice, and Video) wirelessly at any time anywhere in the world.LTE-A delivers speeds of over 42 Mbps and up to 90 Mbps.

Fifth Generation (5G): 5G is a pillar of digital transformation; it is a real improvement on all the previous mobile generation networks. 5G brings three different services for end user like Extreme mobile broadband (eMBB). It offers high-speed internet connectivity, greater bandwidth, moderate latency, UltraHD streaming videos, virtual reality and augmented reality (AR/VR) media, and many more. Massive machine type communication (eMTC), it provides long-range and broadband machine-type communication at a very cost-effective price with less power consumption. eMTC brings a high data rate service, low power, extended coverage via less device complexity through mobile carriers for IoT applications. Ultra-reliable low latency communication (URLLC) offers low-latency and ultra-high reliability, rich quality of service (QoS), which is not possible with traditional mobile network architecture. URLLC is designed for on-demand real-time interaction such as remote surgery, vehicle to vehicle (V2V) communication, industry 4.0, smart grids, intelligent transport system, etc. 5G faster than 4G and offers remote-controlled operation over a reliable network with zero delays. It provides down-link maximum throughput of up to 20 Gbps. In addition, 5G also supports 4G WWWW (4th Generation World Wide Wireless Web) [ 5 ] and is based on Internet protocol version 6 (IPv6) protocol. 5G provides unlimited internet connection at your convenience, anytime, anywhere with extremely high speed, high throughput, low-latency, higher reliability and scalability, and energy-efficient mobile communication technology [ 6 ]. 5G mainly divided in two parts 6 GHz 5G and Millimeter wave(mmWave) 5G.

6 GHz is a mid frequency band which works as a mid point between capacity and coverage to offer perfect environment for 5G connectivity. 6 GHz spectrum will provide high bandwidth with improved network performance. It offers continuous channels that will reduce the need for network densification when mid-band spectrum is not available and it makes 5G connectivity affordable at anytime, anywhere for everyone.

mmWave is an essential technology of 5G network which build high performance network. 5G mmWave offer diverse services that is why all network providers should add on this technology in their 5G deployment planning. There are lots of service providers who deployed 5G mmWave, and their simulation result shows that 5G mmwave is a far less used spectrum. It provides very high speed wireless communication and it also offers ultra-wide bandwidth for next generation mobile network.

The evolution of wireless mobile technologies are presented in Table 1 . The abbreviations used in this paper are mentioned in Table 2 .

Summary of Mobile Technology.

Table of Notations and Abbreviations.

1.2. Key Contributions

The objective of this survey is to provide a detailed guide of 5G key technologies, methods to researchers, and to help with understanding how the recent works addressed 5G problems and developed solutions to tackle the 5G challenges; i.e., what are new methods that must be applied and how can they solve problems? Highlights of the research article are as follows.

• This survey focused on the recent trends and development in the era of 5G and novel contributions by the researcher community and discussed technical details on essential aspects of the 5G advancement.
• In this paper, the evolution of the mobile network from 1G to 5G is presented. In addition, the growth of mobile communication under different attributes is also discussed.
• This paper covers the emerging applications and research groups working on 5G & different research areas in 5G wireless communication network with a descriptive taxonomy.
• This survey discusses the current vision of the 5G networks, advantages, applications, key technologies, and key features. Furthermore, machine learning prospects are also explored with the emerging requirements in the 5G era. The article also focused on technical aspects of 5G IoT Based approaches and optimization techniques for 5G.
• we provide an extensive overview and recent advancement of emerging technologies of 5G mobile network, namely, MIMO, Non-Orthogonal Multiple Access (NOMA), mmWave, Internet of Things (IoT), Machine Learning (ML), and optimization. Also, a technical summary is discussed by highlighting the context of current approaches and corresponding challenges.
• Security challenges and considerations while developing 5G technology are discussed.
• Finally, the paper concludes with the future directives.

The existing survey focused on architecture, key concepts, and implementation challenges and issues. In contrast, this survey covers the state-of-the-art techniques as well as corresponding recent novel developments by researchers. Various recent significant papers are discussed with the key technologies accelerating the development and production of 5G products.

2. Existing Surveys and Their Applicability

In this paper, a detailed survey on various technologies of 5G networks is presented. Various researchers have worked on different technologies of 5G networks. In this section, Table 3 gives a tabular representation of existing surveys of 5G networks. Massive MIMO, NOMA, small cell, mmWave, beamforming, and MEC are the six main pillars that helped to implement 5G networks in real life.

A comparative overview of existing surveys on different technologies of 5G networks.

2.1. Limitations of Existing Surveys

The existing survey focused on architecture, key concepts, and implementation challenges and issues. The numerous current surveys focused on various 5G technologies with different parameters, and the authors did not cover all the technologies of the 5G network in detail with challenges and recent advancements. Few authors worked on MIMO (Non-Orthogonal Multiple Access) NOMA, MEC, small cell technologies. In contrast, some others worked on beamforming, Millimeter-wave (mmWave). But the existing survey did not cover all the technologies of the 5G network from a research and advancement perspective. No detailed survey is available in the market covering all the 5G network technologies and currently published research trade-offs. So, our main aim is to give a detailed study of all the technologies working on the 5G network. In contrast, this survey covers the state-of-the-art techniques as well as corresponding recent novel developments by researchers. Various recent significant papers are discussed with the key technologies accelerating the development and production of 5G products. This survey article collected key information about 5G technology and recent advancements, and it can be a kind of a guide for the reader. This survey provides an umbrella approach to bring multiple solutions and recent improvements in a single place to accelerate the 5G research with the latest key enabling solutions and reviews. A systematic layout representation of the survey in Figure 1 . We provide a state-of-the-art comparative overview of the existing surveys on different technologies of 5G networks in Table 3 .

Systematic layout representation of survey.

2.2. Article Organization

This article is organized under the following sections. Section 2 presents existing surveys and their applicability. In Section 3 , the preliminaries of 5G technology are presented. In Section 4 , recent advances of 5G technology based on Massive MIMO, NOMA, Millimeter Wave, 5G with IoT, machine learning for 5G, and Optimization in 5G are provided. In Section 5 , a description of novel 5G features over 4G is provided. Section 6 covered all the security concerns of the 5G network. Section 7 , 5G technology based on above-stated challenges summarize in tabular form. Finally, Section 8 and Section 9 conclude the study, which paves the path for future research.

3. Preliminary Section

3.1. emerging 5g paradigms and its features.

5G provides very high speed, low latency, and highly salable connectivity between multiple devices and IoT worldwide. 5G will provide a very flexible model to develop a modern generation of applications and industry goals [ 26 , 27 ]. There are many services offered by 5G network architecture are stated below:

Massive machine to machine communications: 5G offers novel, massive machine-to-machine communications [ 28 ], also known as the IoT [ 29 ], that provide connectivity between lots of machines without any involvement of humans. This service enhances the applications of 5G and provides connectivity between agriculture, construction, and industries [ 30 ].

Ultra-reliable low latency communications (URLLC): This service offers real-time management of machines, high-speed vehicle-to-vehicle connectivity, industrial connectivity and security principles, and highly secure transport system, and multiple autonomous actions. Low latency communications also clear up a different area where remote medical care, procedures, and operation are all achievable [ 31 ].

Enhanced mobile broadband: Enhance mobile broadband is an important use case of 5G system, which uses massive MIMO antenna, mmWave, beamforming techniques to offer very high-speed connectivity across a wide range of areas [ 32 ].

For communities: 5G provides a very flexible internet connection between lots of machines to make smart homes, smart schools, smart laboratories, safer and smart automobiles, and good health care centers [ 33 ].

For businesses and industry: As 5G works on higher spectrum ranges from 24 to 100 GHz. This higher frequency range provides secure low latency communication and high-speed wireless connectivity between IoT devices and industry 4.0, which opens a market for end-users to enhance their business models [ 34 ].

New and Emerging technologies: As 5G came up with many new technologies like beamforming, massive MIMO, mmWave, small cell, NOMA, MEC, and network slicing, it introduced many new features to the market. Like virtual reality (VR), users can experience the physical presence of people who are millions of kilometers away from them. Many new technologies like smart homes, smart workplaces, smart schools, smart sports academy also came into the market with this 5G Mobile network model [ 35 ].

3.2. Commercial Service Providers of 5G

5G provides high-speed internet browsing, streaming, and downloading with very high reliability and low latency. 5G network will change your working style, and it will increase new business opportunities and provide innovations that we cannot imagine. This section covers top service providers of 5G network [ 36 , 37 ].

Ericsson: Ericsson is a Swedish multinational networking and telecommunications company, investing around 25.62 billion USD in 5G network, which makes it the biggest telecommunication company. It claims that it is the only company working on all the continents to make the 5G network a global standard for the next generation wireless communication. Ericsson developed the first 5G radio prototype that enables the operators to set up the live field trials in their network, which helps operators understand how 5G reacts. It plays a vital role in the development of 5G hardware. It currently provides 5G services in over 27 countries with content providers like China Mobile, GCI, LGU+, AT&T, Rogers, and many more. It has 100 commercial agreements with different operators as of 2020.

Verizon: It is American multinational telecommunication which was founded in 1983. Verizon started offering 5G services in April 2020, and by December 2020, it has actively provided 5G services in 30 cities of the USA. They planned that by the end of 2021, they would deploy 5G in 30 more new cities. Verizon deployed a 5G network on mmWave, a very high band spectrum between 30 to 300 GHz. As it is a significantly less used spectrum, it provides very high-speed wireless communication. MmWave offers ultra-wide bandwidth for next-generation mobile networks. MmWave is a faster and high-band spectrum that has a limited range. Verizon planned to increase its number of 5G cells by 500% by 2020. Verizon also has an ultra wide-band flagship 5G service which is the best 5G service that increases the market price of Verizon.

Nokia: Nokia is a Finnish multinational telecommunications company which was founded in 1865. Nokia is one of the companies which adopted 5G technology very early. It is developing, researching, and building partnerships with various 5G renders to offer 5G communication as soon as possible. Nokia collaborated with Deutsche Telekom and Hamburg Port Authority and provided them 8000-hectare site for their 5G MoNArch project. Nokia is the only company that supplies 5G technology to all the operators of different countries like AT&T, Sprint, T-Mobile US and Verizon in the USA, Korea Telecom, LG U+ and SK Telecom in South Korea and NTT DOCOMO, KDDI, and SoftBank in Japan. Presently, Nokia has around 150+ agreements and 29 live networks all over the world. Nokia is continuously working hard on 5G technology to expand 5G networks all over the globe.

AT&T: AT&T is an American multinational company that was the first to deploy a 5G network in reality in 2018. They built a gigabit 5G network connection in Waco, TX, Kalamazoo, MI, and South Bend to achieve this. It is the first company that archives 1–2 gigabit per second speed in 2019. AT&T claims that it provides a 5G network connection among 225 million people worldwide by using a 6 GHz spectrum band.

T-Mobile: T-Mobile US (TMUS) is an American wireless network operator which was the first service provider that offers a real 5G nationwide network. The company knew that high-band 5G was not feasible nationwide, so they used a 600 MHz spectrum to build a significant portion of its 5G network. TMUS is planning that by 2024 they will double the total capacity and triple the full 5G capacity of T-Mobile and Sprint combined. The sprint buyout is helping T-Mobile move forward the company’s current market price to 129.98 USD.

Samsung: Samsung started their research in 5G technology in 2011. In 2013, Samsung successfully developed the world’s first adaptive array transceiver technology operating in the millimeter-wave Ka bands for cellular communications. Samsung provides several hundred times faster data transmission than standard 4G for core 5G mobile communication systems. The company achieved a lot of success in the next generation of technology, and it is considered one of the leading companies in the 5G domain.

Qualcomm: Qualcomm is an American multinational corporation in San Diego, California. It is also one of the leading company which is working on 5G chip. Qualcomm’s first 5G modem chip was announced in October 2016, and a prototype was demonstrated in October 2017. Qualcomm mainly focuses on building products while other companies talk about 5G; Qualcomm is building the technologies. According to one magazine, Qualcomm was working on three main areas of 5G networks. Firstly, radios that would use bandwidth from any network it has access to; secondly, creating more extensive ranges of spectrum by combining smaller pieces; and thirdly, a set of services for internet applications.

ZTE Corporation: ZTE Corporation was founded in 1985. It is a partially Chinese state-owned technology company that works in telecommunication. It was a leading company that worked on 4G LTE, and it is still maintaining its value and doing research and tests on 5G. It is the first company that proposed Pre5G technology with some series of solutions.

NEC Corporation: NEC Corporation is a Japanese multinational information technology and electronics corporation headquartered in Minato, Tokyo. ZTE also started their research on 5G, and they introduced a new business concept. NEC’s main aim is to develop 5G NR for the global mobile system and create secure and intelligent technologies to realize 5G services.

Cisco: Cisco is a USA networking hardware company that also sleeves up for 5G network. Cisco’s primary focus is to support 5G in three ways: Service—enable 5G services faster so all service providers can increase their business. Infrastructure—build 5G-oriented infrastructure to implement 5G more quickly. Automation—make a more scalable, flexible, and reliable 5G network. The companies know the importance of 5G, and they want to connect more than 30 billion devices in the next couple of years. Cisco intends to work on network hardening as it is a vital part of 5G network. Cisco used AI with deep learning to develop a 5G Security Architecture, enabling Secure Network Transformation.

3.3. 5G Research Groups

Many research groups from all over the world are working on a 5G wireless mobile network [ 38 ]. These groups are continuously working on various aspects of 5G. The list of those research groups are presented as follows: 5GNOW (5th Generation Non-Orthogonal Waveform for Asynchronous Signaling), NEWCOM (Network of Excellence in Wireless Communication), 5GIC (5G Innovation Center), NYU (New York University) Wireless, 5GPPP (5G Infrastructure Public-Private Partnership), EMPHATIC (Enhanced Multi-carrier Technology for Professional Adhoc and Cell-Based Communication), ETRI(Electronics and Telecommunication Research Institute), METIS (Mobile and wireless communication Enablers for the Twenty-twenty Information Society) [ 39 ]. The various research groups along with the research area are presented in Table 4 .

Research groups working on 5G mobile networks.

3.4. 5G Applications

5G is faster than 4G and offers remote-controlled operation over a reliable network with zero delays. It provides down-link maximum throughput of up to 20 Gbps. In addition, 5G also supports 4G WWWW (4th Generation World Wide Wireless Web) [ 5 ] and is based on Internet protocol version 6 (IPv6) protocol. 5G provides unlimited internet connection at your convenience, anytime, anywhere with extremely high speed, high throughput, low-latency, higher reliability, greater scalablility, and energy-efficient mobile communication technology [ 6 ].

There are lots of applications of 5G mobile network are as follows:

• High-speed mobile network: 5G is an advancement on all the previous mobile network technologies, which offers very high speed downloading speeds 0 of up to 10 to 20 Gbps. The 5G wireless network works as a fiber optic internet connection. 5G is different from all the conventional mobile transmission technologies, and it offers both voice and high-speed data connectivity efficiently. 5G offers very low latency communication of less than a millisecond, useful for autonomous driving and mission-critical applications. 5G will use millimeter waves for data transmission, providing higher bandwidth and a massive data rate than lower LTE bands. As 5 Gis a fast mobile network technology, it will enable virtual access to high processing power and secure and safe access to cloud services and enterprise applications. Small cell is one of the best features of 5G, which brings lots of advantages like high coverage, high-speed data transfer, power saving, easy and fast cloud access, etc. [ 40 ].
• Entertainment and multimedia: In one analysis in 2015, it was found that more than 50 percent of mobile internet traffic was used for video downloading. This trend will surely increase in the future, which will make video streaming more common. 5G will offer High-speed streaming of 4K videos with crystal clear audio, and it will make a high definition virtual world on your mobile. 5G will benefit the entertainment industry as it offers 120 frames per second with high resolution and higher dynamic range video streaming, and HD TV channels can also be accessed on mobile devices without any interruptions. 5G provides low latency high definition communication so augmented reality (AR), and virtual reality (VR) will be very easily implemented in the future. Virtual reality games are trendy these days, and many companies are investing in HD virtual reality games. The 5G network will offer high-speed internet connectivity with a better gaming experience [ 41 ].
• Smart homes : smart home appliances and products are in demand these days. The 5G network makes smart homes more real as it offers high-speed connectivity and monitoring of smart appliances. Smart home appliances are easily accessed and configured from remote locations using the 5G network as it offers very high-speed low latency communication.
• Smart cities: 5G wireless network also helps develop smart cities applications such as automatic traffic management, weather update, local area broadcasting, energy-saving, efficient power supply, smart lighting system, water resource management, crowd management, emergency control, etc.
• Industrial IoT: 5G wireless technology will provide lots of features for future industries such as safety, process tracking, smart packing, shipping, energy efficiency, automation of equipment, predictive maintenance, and logistics. 5G smart sensor technology also offers smarter, safer, cost-effective, and energy-saving industrial IoT operations.
• Smart Farming: 5G technology will play a crucial role in agriculture and smart farming. 5G sensors and GPS technology will help farmers track live attacks on crops and manage them quickly. These smart sensors can also be used for irrigation, pest, insect, and electricity control.
• Autonomous Driving: The 5G wireless network offers very low latency high-speed communication, significant for autonomous driving. It means self-driving cars will come to real life soon with 5G wireless networks. Using 5G autonomous cars can easily communicate with smart traffic signs, objects, and other vehicles running on the road. 5G’s low latency feature makes self-driving more real as every millisecond is essential for autonomous vehicles, decision-making is done in microseconds to avoid accidents.
• Healthcare and mission-critical applications: 5G technology will bring modernization in medicine where doctors and practitioners can perform advanced medical procedures. The 5G network will provide connectivity between all classrooms, so attending seminars and lectures will be easier. Through 5G technology, patients can connect with doctors and take their advice. Scientists are building smart medical devices which can help people with chronic medical conditions. The 5G network will boost the healthcare industry with smart devices, the internet of medical things, smart sensors, HD medical imaging technologies, and smart analytics systems. 5G will help access cloud storage, so accessing healthcare data will be very easy from any location worldwide. Doctors and medical practitioners can easily store and share large files like MRI reports within seconds using the 5G network.
• Satellite Internet: In many remote areas, ground base stations are not available, so 5G will play a crucial role in providing connectivity in such areas. The 5G network will provide connectivity using satellite systems, and the satellite system uses a constellation of multiple small satellites to provide connectivity in urban and rural areas across the world.

4. 5G Technologies

This section describes recent advances of 5G Massive MIMO, 5G NOMA, 5G millimeter wave, 5G IOT, 5G with machine learning, and 5G optimization-based approaches. In addition, the summary is also presented in each subsection that paves the researchers for the future research direction.

4.1. 5G Massive MIMO

Multiple-input-multiple-out (MIMO) is a very important technology for wireless systems. It is used for sending and receiving multiple signals simultaneously over the same radio channel. MIMO plays a very big role in WI-FI, 3G, 4G, and 4G LTE-A networks. MIMO is mainly used to achieve high spectral efficiency and energy efficiency but it was not up to the mark MIMO provides low throughput and very low reliable connectivity. To resolve this, lots of MIMO technology like single user MIMO (SU-MIMO), multiuser MIMO (MU-MIMO) and network MIMO were used. However, these new MIMO also did not still fulfill the demand of end users. Massive MIMO is an advancement of MIMO technology used in the 5G network in which hundreds and thousands of antennas are attached with base stations to increase throughput and spectral efficiency. Multiple transmit and receive antennas are used in massive MIMO to increase the transmission rate and spectral efficiency. When multiple UEs generate downlink traffic simultaneously, massive MIMO gains higher capacity. Massive MIMO uses extra antennas to move energy into smaller regions of space to increase spectral efficiency and throughput [ 43 ]. In traditional systems data collection from smart sensors is a complex task as it increases latency, reduced data rate and reduced reliability. While massive MIMO with beamforming and huge multiplexing techniques can sense data from different sensors with low latency, high data rate and higher reliability. Massive MIMO will help in transmitting the data in real-time collected from different sensors to central monitoring locations for smart sensor applications like self-driving cars, healthcare centers, smart grids, smart cities, smart highways, smart homes, and smart enterprises [ 44 ].

Highlights of 5G Massive MIMO technology are as follows:

• Data rate: Massive MIMO is advised as the one of the dominant technologies to provide wireless high speed and high data rate in the gigabits per seconds.
• The relationship between wave frequency and antenna size: Both are inversely proportional to each other. It means lower frequency signals need a bigger antenna and vise versa.

Pictorial representation of multi-input and multi-output (MIMO).

• MIMO role in 5G: Massive MIMO will play a crucial role in the deployment of future 5G mobile communication as greater spectral and energy efficiency could be enabled.

State-of-the-Art Approaches

Plenty of approaches were proposed to resolve the issues of conventional MIMO [ 7 ].

The MIMO multirate, feed-forward controller is suggested by Mae et al. [ 46 ]. In the simulation, the proposed model generates the smooth control input, unlike the conventional MIMO, which generates oscillated control inputs. It also outperformed concerning the error rate. However, a combination of multirate and single rate can be used for better results.

The performance of stand-alone MIMO, distributed MIMO with and without corporation MIMO, was investigated by Panzner et al. [ 47 ]. In addition, an idea about the integration of large scale in the 5G technology was also presented. In the experimental analysis, different MIMO configurations are considered. The variation in the ratio of overall transmit antennas to spatial is deemed step-wise from equality to ten.

The simulation of massive MIMO noncooperative and cooperative systems for down-link behavior was performed by He et al. [ 48 ]. It depends on present LTE systems, which deal with various antennas in the base station set-up. It was observed that collaboration in different BS improves the system behaviors, whereas throughput is reduced slightly in this approach. However, a new method can be developed which can enhance both system behavior and throughput.

In [ 8 ], different approaches that increased the energy efficiency benefits provided by massive MIMO were presented. They analyzed the massive MIMO technology and described the detailed design of the energy consumption model for massive MIMO systems. This article has explored several techniques to enhance massive MIMO systems’ energy efficiency (EE) gains. This paper reviews standard EE-maximization approaches for the conventional massive MIMO systems, namely, scaling number of antennas, real-time implementing low-complexity operations at the base station (BS), power amplifier losses minimization, and radio frequency (RF) chain minimization requirements. In addition, open research direction is also identified.

In [ 49 ], various existing approaches based on different antenna selection and scheduling, user selection and scheduling, and joint antenna and user scheduling methods adopted in massive MIMO systems are presented in this paper. The objective of this survey article was to make awareness about the current research and future research direction in MIMO for systems. They analyzed that complete utilization of resources and bandwidth was the most crucial factor which enhances the sum rate.

In [ 50 ], authors discussed the development of various techniques for pilot contamination. To calculate the impact of pilot contamination in time division duplex (TDD) massive MIMO system, TDD and frequency division duplexing FDD patterns in massive MIMO techniques are used. They discussed different issues in pilot contamination in TDD massive MIMO systems with all the possible future directions of research. They also classified various techniques to generate the channel information for both pilot-based and subspace-based approaches.

In [ 19 ], the authors defined the uplink and downlink services for a massive MIMO system. In addition, it maintains a performance matrix that measures the impact of pilot contamination on different performances. They also examined the various application of massive MIMO such as small cells, orthogonal frequency-division multiplexing (OFDM) schemes, massive MIMO IEEE 802, 3rd generation partnership project (3GPP) specifications, and higher frequency bands. They considered their research work crucial for cutting edge massive MIMO and covered many issues like system throughput performance and channel state acquisition at higher frequencies.

In [ 13 ], various approaches were suggested for MIMO future generation wireless communication. They made a comparative study based on performance indicators such as peak data rate, energy efficiency, latency, throughput, etc. The key findings of this survey are as follows: (1) spatial multiplexing improves the energy efficiency; (2) design of MIMO play a vital role in the enhancement of throughput; (3) enhancement of mMIMO focusing on energy & spectral performance; (4) discussed the future challenges to improve the system design.

In [ 51 ], the study of large-scale MIMO systems for an energy-efficient system sharing method was presented. For the resource allocation, circuit energy and transmit energy expenditures were taken into consideration. In addition, the optimization techniques were applied for an energy-efficient resource sharing system to enlarge the energy efficiency for individual QoS and energy constraints. The author also examined the BS configuration, which includes homogeneous and heterogeneous UEs. While simulating, they discussed that the total number of transmit antennas plays a vital role in boosting energy efficiency. They highlighted that the highest energy efficiency was obtained when the BS was set up with 100 antennas that serve 20 UEs.

This section includes various works done on 5G MIMO technology by different author’s. Table 5 shows how different author’s worked on improvement of various parameters such as throughput, latency, energy efficiency, and spectral efficiency with 5G MIMO technology.

Summary of massive MIMO-based approaches in 5G technology.

4.2. 5G Non-Orthogonal Multiple Access (NOMA)

NOMA is a very important radio access technology used in next generation wireless communication. Compared to previous orthogonal multiple access techniques, NOMA offers lots of benefits like high spectrum efficiency, low latency with high reliability and high speed massive connectivity. NOMA mainly works on a baseline to serve multiple users with the same resources in terms of time, space and frequency. NOMA is mainly divided into two main categories one is code domain NOMA and another is power domain NOMA. Code-domain NOMA can improve the spectral efficiency of mMIMO, which improves the connectivity in 5G wireless communication. Code-domain NOMA was divided into some more multiple access techniques like sparse code multiple access, lattice-partition multiple access, multi-user shared access and pattern-division multiple access [ 52 ]. Power-domain NOMA is widely used in 5G wireless networks as it performs well with various wireless communication techniques such as MIMO, beamforming, space-time coding, network coding, full-duplex and cooperative communication etc. [ 53 ]. The conventional orthogonal frequency-division multiple access (OFDMA) used by 3GPP in 4G LTE network provides very low spectral efficiency when bandwidth resources are allocated to users with low channel state information (CSI). NOMA resolved this issue as it enables users to access all the subcarrier channels so bandwidth resources allocated to the users with low CSI can still be accessed by the users with strong CSI which increases the spectral efficiency. The 5G network will support heterogeneous architecture in which small cell and macro base stations work for spectrum sharing. NOMA is a key technology of the 5G wireless system which is very helpful for heterogeneous networks as multiple users can share their data in a small cell using the NOMA principle.The NOMA is helpful in various applications like ultra-dense networks (UDN), machine to machine (M2M) communication and massive machine type communication (mMTC). As NOMA provides lots of features it has some challenges too such as NOMA needs huge computational power for a large number of users at high data rates to run the SIC algorithms. Second, when users are moving from the networks, to manage power allocation optimization is a challenging task for NOMA [ 54 ]. Hybrid NOMA (HNOMA) is a combination of power-domain and code-domain NOMA. HNOMA uses both power differences and orthogonal resources for transmission among multiple users. As HNOMA is using both power-domain NOMA and code-domain NOMA it can achieve higher spectral efficiency than Power-domain NOMA and code-domain NOMA. In HNOMA multiple groups can simultaneously transmit signals at the same time. It uses a message passing algorithm (MPA) and successive interference cancellation (SIC)-based detection at the base station for these groups [ 55 ].

Highlights of 5G NOMA technology as follows:

Pictorial representation of orthogonal and Non-Orthogonal Multiple Access (NOMA).

• NOMA provides higher data rates and resolves all the loop holes of OMA that makes 5G mobile network more scalable and reliable.
• As multiple users use same frequency band simultaneously it increases the performance of whole network.
• To setup intracell and intercell interference NOMA provides nonorthogonal transmission on the transmitter end.
• The primary fundamental of NOMA is to improve the spectrum efficiency by strengthening the ramification of receiver.

State-of-the-Art of Approaches

A plenty of approaches were developed to address the various issues in NOMA.

A novel approach to address the multiple receiving signals at the same frequency is proposed in [ 22 ]. In NOMA, multiple users use the same sub-carrier, which improves the fairness and throughput of the system. As a nonorthogonal method is used among multiple users, at the time of retrieving the user’s signal at the receiver’s end, joint processing is required. They proposed solutions to optimize the receiver and the radio resource allocation of uplink NOMA. Firstly, the authors proposed an iterative MUDD which utilizes the information produced by the channel decoder to improve the performance of the multiuser detector. After that, the author suggested a power allocation and novel subcarrier that enhances the users’ weighted sum rate for the NOMA scheme. Their proposed model showed that NOMA performed well as compared to OFDM in terms of fairness and efficiency.

In [ 53 ], the author’s reviewed a power-domain NOMA that uses superposition coding (SC) and successive interference cancellation (SIC) at the transmitter and the receiver end. Lots of analyses were held that described that NOMA effectively satisfies user data rate demands and network-level of 5G technologies. The paper presented a complete review of recent advances in the 5G NOMA system. It showed the comparative analysis regarding allocation procedures, user fairness, state-of-the-art efficiency evaluation, user pairing pattern, etc. The study also analyzes NOMA’s behavior when working with other wireless communication techniques, namely, beamforming, MIMO, cooperative connections, network, space-time coding, etc.

In [ 9 ], the authors proposed NOMA with MEC, which improves the QoS as well as reduces the latency of the 5G wireless network. This model increases the uplink NOMA by decreasing the user’s uplink energy consumption. They formulated an optimized NOMA framework that reduces the energy consumption of MEC by using computing and communication resource allocation, user clustering, and transmit powers.

In [ 10 ], the authors proposed a model which investigates outage probability under average channel state information CSI and data rate in full CSI to resolve the problem of optimal power allocation, which increase the NOMA downlink system among users. They developed simple low-complexity algorithms to provide the optimal solution. The obtained simulation results showed NOMA’s efficiency, achieving higher performance fairness compared to the TDMA configurations. It was observed from the results that NOMA, through the appropriate power amplifiers (PA), ensures the high-performance fairness requirement for the future 5G wireless communication networks.

In [ 56 ], researchers discussed that the NOMA technology and waveform modulation techniques had been used in the 5G mobile network. Therefore, this research gave a detailed survey of non-orthogonal waveform modulation techniques and NOMA schemes for next-generation mobile networks. By analyzing and comparing multiple access technologies, they considered the future evolution of these technologies for 5G mobile communication.

In [ 57 ], the authors surveyed non-orthogonal multiple access (NOMA) from the development phase to the recent developments. They have also compared NOMA techniques with traditional OMA techniques concerning information theory. The author discussed the NOMA schemes categorically as power and code domain, including the design principles, operating principles, and features. Comparison is based upon the system’s performance, spectral efficiency, and the receiver’s complexity. Also discussed are the future challenges, open issues, and their expectations of NOMA and how it will support the key requirements of 5G mobile communication systems with massive connectivity and low latency.

In [ 17 ], authors present the first review of an elementary NOMA model with two users, which clarify its central precepts. After that, a general design with multicarrier supports with a random number of users on each sub-carrier is analyzed. In performance evaluation with the existing approaches, resource sharing and multiple-input multiple-output NOMA are examined. Furthermore, they took the key elements of NOMA and its potential research demands. Finally, they reviewed the two-user SC-NOMA design and a multi-user MC-NOMA design to highlight NOMA’s basic approaches and conventions. They also present the research study about the performance examination, resource assignment, and MIMO in NOMA.

In this section, various works by different authors done on 5G NOMA technology is covered. Table 6 shows how other authors worked on the improvement of various parameters such as spectral efficiency, fairness, and computing capacity with 5G NOMA technology.

Summary of NOMA-based approaches in 5G technology.

4.3. 5G Millimeter Wave (mmWave)

Millimeter wave is an extremely high frequency band, which is very useful for 5G wireless networks. MmWave uses 30 GHz to 300 GHz spectrum band for transmission. The frequency band between 30 GHz to 300 GHz is known as mmWave because these waves have wavelengths between 1 to 10 mm. Till now radar systems and satellites are only using mmWave as these are very fast frequency bands which provide very high speed wireless communication. Many mobile network providers also started mmWave for transmitting data between base stations. Using two ways the speed of data transmission can be improved one is by increasing spectrum utilization and second is by increasing spectrum bandwidth. Out of these two approaches increasing bandwidth is quite easy and better. The frequency band below 5 GHz is very crowded as many technologies are using it so to boost up the data transmission rate 5G wireless network uses mmWave technology which instead of increasing spectrum utilization, increases the spectrum bandwidth [ 58 ]. To maximize the signal bandwidth in wireless communication the carrier frequency should also be increased by 5% because the signal bandwidth is directly proportional to carrier frequencies. The frequency band between 28 GHz to 60 GHz is very useful for 5G wireless communication as 28 GHz frequency band offers up to 1 GHz spectrum bandwidth and 60 GHz frequency band offers 2 GHz spectrum bandwidth. 4G LTE provides 2 GHz carrier frequency which offers only 100 MHz spectrum bandwidth. However, the use of mmWave increases the spectrum bandwidth 10 times, which leads to better transmission speeds [ 59 , 60 ].

Highlights of 5G mmWave are as follows:

Pictorial representation of millimeter wave.

• The 5G mmWave offer three advantages: (1) MmWave is very less used new Band, (2) MmWave signals carry more data than lower frequency wave, and (3) MmWave can be incorporated with MIMO antenna with the potential to offer a higher magnitude capacity compared to current communication systems.

In [ 11 ], the authors presented the survey of mmWave communications for 5G. The advantage of mmWave communications is adaptability, i.e., it supports the architectures and protocols up-gradation, which consists of integrated circuits, systems, etc. The authors over-viewed the present solutions and examined them concerning effectiveness, performance, and complexity. They also discussed the open research issues of mmWave communications in 5G concerning the software-defined network (SDN) architecture, network state information, efficient regulation techniques, and the heterogeneous system.

In [ 61 ], the authors present the recent work done by investigators in 5G; they discussed the design issues and demands of mmWave 5G antennas for cellular handsets. After that, they designed a small size and low-profile 60 GHz array of antenna units that contain 3D planer mesh-grid antenna elements. For the future prospect, a framework is designed in which antenna components are used to operate cellular handsets on mmWave 5G smartphones. In addition, they cross-checked the mesh-grid array of antennas with the polarized beam for upcoming hardware challenges.

In [ 12 ], the authors considered the suitability of the mmWave band for 5G cellular systems. They suggested a resource allocation system for concurrent D2D communications in mmWave 5G cellular systems, and it improves network efficiency and maintains network connectivity. This research article can serve as guidance for simulating D2D communications in mmWave 5G cellular systems. Massive mmWave BS may be set up to obtain a high delivery rate and aggregate efficiency. Therefore, many wireless users can hand off frequently between the mmWave base terminals, and it emerges the demand to search the neighbor having better network connectivity.

In [ 62 ], the authors provided a brief description of the cellular spectrum which ranges from 1 GHz to 3 GHz and is very crowed. In addition, they presented various noteworthy factors to set up mmWave communications in 5G, namely, channel characteristics regarding mmWave signal attenuation due to free space propagation, atmospheric gaseous, and rain. In addition, hybrid beamforming architecture in the mmWave technique is analyzed. They also suggested methods for the blockage effect in mmWave communications due to penetration damage. Finally, the authors have studied designing the mmWave transmission with small beams in nonorthogonal device-to-device communication.

This section covered various works done on 5G mmWave technology. The Table 7 shows how different author’s worked on the improvement of various parameters i.e., transmission rate, coverage, and cost, with 5G mmWave technology.

Summary of existing mmWave-based approaches in 5G technology.

4.4. 5G IoT Based Approaches

The 5G mobile network plays a big role in developing the Internet of Things (IoT). IoT will connect lots of things with the internet like appliances, sensors, devices, objects, and applications. These applications will collect lots of data from different devices and sensors. 5G will provide very high speed internet connectivity for data collection, transmission, control, and processing. 5G is a flexible network with unused spectrum availability and it offers very low cost deployment that is why it is the most efficient technology for IoT [ 63 ]. In many areas, 5G provides benefits to IoT, and below are some examples:

Smart homes: smart home appliances and products are in demand these days. The 5G network makes smart homes more real as it offers high speed connectivity and monitoring of smart appliances. Smart home appliances are easily accessed and configured from remote locations using the 5G network, as it offers very high speed low latency communication.

Smart cities: 5G wireless network also helps in developing smart cities applications such as automatic traffic management, weather update, local area broadcasting, energy saving, efficient power supply, smart lighting system, water resource management, crowd management, emergency control, etc.

Industrial IoT: 5G wireless technology will provide lots of features for future industries such as safety, process tracking, smart packing, shipping, energy efficiency, automation of equipment, predictive maintenance and logistics. 5G smart sensor technology also offers smarter, safer, cost effective, and energy-saving industrial operation for industrial IoT.

Smart Farming: 5G technology will play a crucial role for agriculture and smart farming. 5G sensors and GPS technology will help farmers to track live attacks on crops and manage them quickly. These smart sensors can also be used for irrigation control, pest control, insect control, and electricity control.

Autonomous Driving: 5G wireless network offers very low latency high speed communication which is very significant for autonomous driving. It means self-driving cars will come to real life soon with 5G wireless networks. Using 5G autonomous cars can easily communicate with smart traffic signs, objects and other vehicles running on the road. 5G’s low latency feature makes self-driving more real as every millisecond is important for autonomous vehicles, decision taking is performed in microseconds to avoid accidents [ 64 ].

Highlights of 5G IoT are as follows:

Pictorial representation of IoT with 5G.

• 5G with IoT is a new feature of next-generation mobile communication, which provides a high-speed internet connection between moderated devices. 5G IoT also offers smart homes, smart devices, sensors, smart transportation systems, smart industries, etc., for end-users to make them smarter.
• IoT deals with moderate devices which connect through the internet. The approach of the IoT has made the consideration of the research associated with the outcome of providing wearable, smart-phones, sensors, smart transportation systems, smart devices, washing machines, tablets, etc., and these diverse systems are associated to a common interface with the intelligence to connect.
• Significant IoT applications include private healthcare systems, traffic management, industrial management, and tactile internet, etc.

Plenty of approaches is devised to address the issues of IoT [ 14 , 65 , 66 ].

In [ 65 ], the paper focuses on 5G mobile systems due to the emerging trends and developing technologies, which results in the exponential traffic growth in IoT. The author surveyed the challenges and demands during deployment of the massive IoT applications with the main focus on mobile networking. The author reviewed the features of standard IoT infrastructure, along with the cellular-based, low-power wide-area technologies (LPWA) such as eMTC, extended coverage (EC)-GSM-IoT, as well as noncellular, low-power wide-area (LPWA) technologies such as SigFox, LoRa etc.

In [ 14 ], the authors presented how 5G technology copes with the various issues of IoT today. It provides a brief review of existing and forming 5G architectures. The survey indicates the role of 5G in the foundation of the IoT ecosystem. IoT and 5G can easily combine with improved wireless technologies to set up the same ecosystem that can fulfill the current requirement for IoT devices. 5G can alter nature and will help to expand the development of IoT devices. As the process of 5G unfolds, global associations will find essentials for setting up a cross-industry engagement in determining and enlarging the 5G system.

In [ 66 ], the author introduced an IoT authentication scheme in a 5G network, with more excellent reliability and dynamic. The scheme proposed a privacy-protected procedure for selecting slices; it provided an additional fog node for proper data transmission and service types of the subscribers, along with service-oriented authentication and key understanding to maintain the secrecy, precision of users, and confidentiality of service factors. Users anonymously identify the IoT servers and develop a vital channel for service accessibility and data cached on local fog nodes and remote IoT servers. The author performed a simulation to manifest the security and privacy preservation of the user over the network.

This section covered various works done on 5G IoT by multiple authors. Table 8 shows how different author’s worked on the improvement of numerous parameters, i.e., data rate, security requirement, and performance with 5G IoT.

Summary of IoT-based approaches in 5G technology.

4.5. Machine Learning Techniques for 5G

Various machine learning (ML) techniques were applied in 5G networks and mobile communication. It provides a solution to multiple complex problems, which requires a lot of hand-tuning. ML techniques can be broadly classified as supervised, unsupervised, and reinforcement learning. Let’s discuss each learning technique separately and where it impacts the 5G network.

Supervised Learning, where user works with labeled data; some 5G network problems can be further categorized as classification and regression problems. Some regression problems such as scheduling nodes in 5G and energy availability can be predicted using Linear Regression (LR) algorithm. To accurately predict the bandwidth and frequency allocation Statistical Logistic Regression (SLR) is applied. Some supervised classifiers are applied to predict the network demand and allocate network resources based on the connectivity performance; it signifies the topology setup and bit rates. Support Vector Machine (SVM) and NN-based approximation algorithms are used for channel learning based on observable channel state information. Deep Neural Network (DNN) is also employed to extract solutions for predicting beamforming vectors at the BS’s by taking mapping functions and uplink pilot signals into considerations.

In unsupervised Learning, where the user works with unlabeled data, various clustering techniques are applied to enhance network performance and connectivity without interruptions. K-means clustering reduces the data travel by storing data centers content into clusters. It optimizes the handover estimation based on mobility pattern and selection of relay nodes in the V2V network. Hierarchical clustering reduces network failure by detecting the intrusion in the mobile wireless network; unsupervised soft clustering helps in reducing latency by clustering fog nodes. The nonparametric Bayesian unsupervised learning technique reduces traffic in the network by actively serving the user’s requests and demands. Other unsupervised learning techniques such as Adversarial Auto Encoders (AAE) and Affinity Propagation Clustering techniques detect irregular behavior in the wireless spectrum and manage resources for ultradense small cells, respectively.

In case of an uncertain environment in the 5G wireless network, reinforcement learning (RL) techniques are employed to solve some problems. Actor-critic reinforcement learning is used for user scheduling and resource allocation in the network. Markov decision process (MDP) and Partially Observable MDP (POMDP) is used for Quality of Experience (QoE)-based handover decision-making for Hetnets. Controls packet call admission in HetNets and channel access process for secondary users in a Cognitive Radio Network (CRN). Deep RL is applied to decide the communication channel and mobility and speeds up the secondary user’s learning rate using an antijamming strategy. Deep RL is employed in various 5G network application parameters such as resource allocation and security [ 67 ]. Table 9 shows the state-of-the-art ML-based solution for 5G network.

The state-of-the-art ML-based solution for 5G network.

Highlights of machine learning techniques for 5G are as follows:

Pictorial representation of machine learning (ML) in 5G.

• In ML, a model will be defined which fulfills the desired requirements through which desired results are obtained. In the later stage, it examines accuracy from obtained results.
• ML plays a vital role in 5G network analysis for threat detection, network load prediction, final arrangement, and network formation. Searching for a better balance between power, length of antennas, area, and network thickness crossed with the spontaneous use of services in the universe of individual users and types of devices.

In [ 79 ], author’s firstly describes the demands for the traditional authentication procedures and benefits of intelligent authentication. The intelligent authentication method was established to improve security practice in 5G-and-beyond wireless communication systems. Thereafter, the machine learning paradigms for intelligent authentication were organized into parametric and non-parametric research methods, as well as supervised, unsupervised, and reinforcement learning approaches. As a outcome, machine learning techniques provide a new paradigm into authentication under diverse network conditions and unstable dynamics. In addition, prompt intelligence to the security management to obtain cost-effective, better reliable, model-free, continuous, and situation-aware authentication.

In [ 68 ], the authors proposed a machine learning-based model to predict the traffic load at a particular location. They used a mobile network traffic dataset to train a model that can calculate the total number of user requests at a time. To launch access and mobility management function (AMF) instances according to the requirement as there were no predictions of user request the performance automatically degrade as AMF does not handle these requests at a time. Earlier threshold-based techniques were used to predict the traffic load, but that approach took too much time; therefore, the authors proposed RNN algorithm-based ML to predict the traffic load, which gives efficient results.

In [ 15 ], authors discussed the issue of network slice admission, resource allocation among subscribers, and how to maximize the profit of infrastructure providers. The author proposed a network slice admission control algorithm based on SMDP (decision-making process) that guarantees the subscribers’ best acceptance policies and satisfiability (tenants). They also suggested novel N3AC, a neural network-based algorithm that optimizes performance under various configurations, significantly outperforms practical and straightforward approaches.

This section includes various works done on 5G ML by different authors. Table 10 shows the state-of-the-art work on the improvement of various parameters such as energy efficiency, Quality of Services (QoS), and latency with 5G ML.

The state-of-the-art ML-based approaches in 5G technology.

4.6. Optimization Techniques for 5G

Optimization techniques may be applied to capture NP-Complete or NP-Hard problems in 5G technology. This section briefly describes various research works suggested for 5G technology based on optimization techniques.

In [ 80 ], Massive MIMO technology is used in 5G mobile network to make it more flexible and scalable. The MIMO implementation in 5G needs a significant number of radio frequencies is required in the RF circuit that increases the cost and energy consumption of the 5G network. This paper provides a solution that increases the cost efficiency and energy efficiency with many radio frequency chains for a 5G wireless communication network. They give an optimized energy efficient technique for MIMO antenna and mmWave technologies based 5G mobile communication network. The proposed Energy Efficient Hybrid Precoding (EEHP) algorithm to increase the energy efficiency for the 5G wireless network. This algorithm minimizes the cost of an RF circuit with a large number of RF chains.

In [ 16 ], authors have discussed the growing demand for energy efficiency in the next-generation networks. In the last decade, they have figured out the things in wireless transmissions, which proved a change towards pursuing green communication for the next generation system. The importance of adopting the correct EE metric was also reviewed. Further, they worked through the different approaches that can be applied in the future for increasing the network’s energy and posed a summary of the work that was completed previously to enhance the energy productivity of the network using these capabilities. A system design for EE development using relay selection was also characterized, along with an observation of distinct algorithms applied for EE in relay-based ecosystems.

In [ 81 ], authors presented how AI-based approach is used to the setup of Self Organizing Network (SON) functionalities for radio access network (RAN) design and optimization. They used a machine learning approach to predict the results for 5G SON functionalities. Firstly, the input was taken from various sources; then, prediction and clustering-based machine learning models were applied to produce the results. Multiple AI-based devices were used to extract the knowledge analysis to execute SON functionalities smoothly. Based on results, they tested how self-optimization, self-testing, and self-designing are done for SON. The author also describes how the proposed mechanism classifies in different orders.

In [ 82 ], investigators examined the working of OFDM in various channel environments. They also figured out the changes in frame duration of the 5G TDD frame design. Subcarrier spacing is beneficial to obtain a small frame length with control overhead. They provided various techniques to reduce the growing guard period (GP) and cyclic prefix (CP) like complete utilization of multiple subcarrier spacing, management and data parts of frame at receiver end, various uses of timing advance (TA) or total control of flexible CP size.

This section includes various works that were done on 5G optimization by different authors. Table 11 shows how other authors worked on the improvement of multiple parameters such as energy efficiency, power optimization, and latency with 5G optimization.

Summary of Optimization Based Approaches in 5G Technology.

5. Description of Novel 5G Features over 4G

This section presents descriptions of various novel features of 5G, namely, the concept of small cell, beamforming, and MEC.

5.1. Small Cell

Small cells are low-powered cellular radio access nodes which work in the range of 10 meters to a few kilometers. Small cells play a very important role in implementation of the 5G wireless network. Small cells are low power base stations which cover small areas. Small cells are quite similar with all the previous cells used in various wireless networks. However, these cells have some advantages like they can work with low power and they are also capable of working with high data rates. Small cells help in rollout of 5G network with ultra high speed and low latency communication. Small cells in the 5G network use some new technologies like MIMO, beamforming, and mmWave for high speed data transmission. The design of small cells hardware is very simple so its implementation is quite easier and faster. There are three types of small cell tower available in the market. Femtocells, picocells, and microcells [ 83 ]. As shown in the Table 12 .

Types of Small cells.

MmWave is a very high band spectrum between 30 to 300 GHz. As it is a significantly less used spectrum, it provides very high-speed wireless communication. MmWave offers ultra-wide bandwidth for next-generation mobile networks. MmWave has lots of advantages, but it has some disadvantages, too, such as mmWave signals are very high-frequency signals, so they have more collision with obstacles in the air which cause the signals loses energy quickly. Buildings and trees also block MmWave signals, so these signals cover a shorter distance. To resolve these issues, multiple small cell stations are installed to cover the gap between end-user and base station [ 18 ]. Small cell covers a very shorter range, so the installation of a small cell depends on the population of a particular area. Generally, in a populated place, the distance between each small cell varies from 10 to 90 meters. In the survey [ 20 ], various authors implemented small cells with massive MIMO simultaneously. They also reviewed multiple technologies used in 5G like beamforming, small cell, massive MIMO, NOMA, device to device (D2D) communication. Various problems like interference management, spectral efficiency, resource management, energy efficiency, and backhauling are discussed. The author also gave a detailed presentation of all the issues occurring while implementing small cells with various 5G technologies. As shown in the Figure 7 , mmWave has a higher range, so it can be easily blocked by the obstacles as shown in Figure 7 a. This is one of the key concerns of millimeter-wave signal transmission. To solve this issue, the small cell can be placed at a short distance to transmit the signals easily, as shown in Figure 7 b.

Pictorial representation of communication with and without small cells.

5.2. Beamforming

Beamforming is a key technology of wireless networks which transmits the signals in a directional manner. 5G beamforming making a strong wireless connection toward a receiving end. In conventional systems when small cells are not using beamforming, moving signals to particular areas is quite difficult. Beamforming counter this issue using beamforming small cells are able to transmit the signals in particular direction towards a device like mobile phone, laptops, autonomous vehicle and IoT devices. Beamforming is improving the efficiency and saves the energy of the 5G network. Beamforming is broadly divided into three categories: Digital beamforming, analog beamforming and hybrid beamforming. Digital beamforming: multiuser MIMO is equal to digital beamforming which is mainly used in LTE Advanced Pro and in 5G NR. In digital beamforming the same frequency or time resources can be used to transmit the data to multiple users at the same time which improves the cell capacity of wireless networks. Analog Beamforming: In mmWave frequency range 5G NR analog beamforming is a very important approach which improves the coverage. In digital beamforming there are chances of high pathloss in mmWave as only one beam per set of antenna is formed. While the analog beamforming saves high pathloss in mmWave. Hybrid beamforming: hybrid beamforming is a combination of both analog beamforming and digital beamforming. In the implementation of MmWave in 5G network hybrid beamforming will be used [ 84 ].

Wireless signals in the 4G network are spreading in large areas, and nature is not Omnidirectional. Thus, energy depletes rapidly, and users who are accessing these signals also face interference problems. The beamforming technique is used in the 5G network to resolve this issue. In beamforming signals are directional. They move like a laser beam from the base station to the user, so signals seem to be traveling in an invisible cable. Beamforming helps achieve a faster data rate; as the signals are directional, it leads to less energy consumption and less interference. In [ 21 ], investigators evolve some techniques which reduce interference and increase system efficiency of the 5G mobile network. In this survey article, the authors covered various challenges faced while designing an optimized beamforming algorithm. Mainly focused on different design parameters such as performance evaluation and power consumption. In addition, they also described various issues related to beamforming like CSI, computation complexity, and antenna correlation. They also covered various research to cover how beamforming helps implement MIMO in next-generation mobile networks [ 85 ]. Figure 8 shows the pictorial representation of communication with and without using beamforming.

Pictorial Representation of communication with and without using beamforming.

5.3. Mobile Edge Computing

Mobile Edge Computing (MEC) [ 24 ]: MEC is an extended version of cloud computing that brings cloud resources closer to the end-user. When we talk about computing, the very first thing that comes to our mind is cloud computing. Cloud computing is a very famous technology that offers many services to end-user. Still, cloud computing has many drawbacks. The services available in the cloud are too far from end-users that create latency, and cloud user needs to download the complete application before use, which also increases the burden to the device [ 86 ]. MEC creates an edge between the end-user and cloud server, bringing cloud computing closer to the end-user. Now, all the services, namely, video conferencing, virtual software, etc., are offered by this edge that improves cloud computing performance. Another essential feature of MEC is that the application is split into two parts, which, first one is available at cloud server, and the second is at the user’s device. Therefore, the user need not download the complete application on his device that increases the performance of the end user’s device. Furthermore, MEC provides cloud services at very low latency and less bandwidth. In [ 23 , 87 ], the author’s investigation proved that successful deployment of MEC in 5G network increases the overall performance of 5G architecture. Graphical differentiation between cloud computing and mobile edge computing is presented in Figure 9 .

Pictorial representation of cloud computing vs. mobile edge computing.

6. 5G Security

Security is the key feature in the telecommunication network industry, which is necessary at various layers, to handle 5G network security in applications such as IoT, Digital forensics, IDS and many more [ 88 , 89 ]. The authors [ 90 ], discussed the background of 5G and its security concerns, challenges and future directions. The author also introduced the blockchain technology that can be incorporated with the IoT to overcome the challenges in IoT. The paper aims to create a security framework which can be incorporated with the LTE advanced network, and effective in terms of cost, deployment and QoS. In [ 91 ], author surveyed various form of attacks, the security challenges, security solutions with respect to the affected technology such as SDN, Network function virtualization (NFV), Mobile Clouds and MEC, and security standardizations of 5G, i.e., 3GPP, 5GPPP, Internet Engineering Task Force (IETF), Next Generation Mobile Networks (NGMN), European Telecommunications Standards Institute (ETSI). In [ 92 ], author elaborated various technological aspects, security issues and their existing solutions and also mentioned the new emerging technological paradigms for 5G security such as blockchain, quantum cryptography, AI, SDN, CPS, MEC, D2D. The author aims to create new security frameworks for 5G for further use of this technology in development of smart cities, transportation and healthcare. In [ 93 ], author analyzed the threats and dark threat, security aspects concerned with SDN and NFV, also their Commercial & Industrial Security Corporation (CISCO) 5G vision and new security innovations with respect to the new evolving architectures of 5G [ 94 ].

AuthenticationThe identification of the user in any network is made with the help of authentication. The different mobile network generations from 1G to 5G have used multiple techniques for user authentication. 5G utilizes the 5G Authentication and Key Agreement (AKA) authentication method, which shares a cryptographic key between user equipment (UE) and its home network and establishes a mutual authentication process between the both [ 95 ].

Access Control To restrict the accessibility in the network, 5G supports access control mechanisms to provide a secure and safe environment to the users and is controlled by network providers. 5G uses simple public key infrastructure (PKI) certificates for authenticating access in the 5G network. PKI put forward a secure and dynamic environment for the 5G network. The simple PKI technique provides flexibility to the 5G network; it can scale up and scale down as per the user traffic in the network [ 96 , 97 ].

Communication Security 5G deals to provide high data bandwidth, low latency, and better signal coverage. Therefore secure communication is the key concern in the 5G network. UE, mobile operators, core network, and access networks are the main focal point for the attackers in 5G communication. Some of the common attacks in communication at various segments are Botnet, message insertion, micro-cell, distributed denial of service (DDoS), and transport layer security (TLS)/secure sockets layer (SSL) attacks [ 98 , 99 ].

Encryption The confidentiality of the user and the network is done using encryption techniques. As 5G offers multiple services, end-to-end (E2E) encryption is the most suitable technique applied over various segments in the 5G network. Encryption forbids unauthorized access to the network and maintains the data privacy of the user. To encrypt the radio traffic at Packet Data Convergence Protocol (PDCP) layer, three 128-bits keys are applied at the user plane, nonaccess stratum (NAS), and access stratum (AS) [ 100 ].

7. Summary of 5G Technology Based on Above-Stated Challenges

In this section, various issues addressed by investigators in 5G technologies are presented in Table 13 . In addition, different parameters are considered, such as throughput, latency, energy efficiency, data rate, spectral efficiency, fairness & computing capacity, transmission rate, coverage, cost, security requirement, performance, QoS, power optimization, etc., indexed from R1 to R14.

Summary of 5G Technology above stated challenges (R1:Throughput, R2:Latency, R3:Energy Efficiency, R4:Data Rate, R5:Spectral efficiency, R6:Fairness & Computing Capacity, R7:Transmission Rate, R8:Coverage, R9:Cost, R10:Security requirement, R11:Performance, R12:Quality of Services (QoS), R13:Power Optimization).

8. Conclusions

This survey article illustrates the emergence of 5G, its evolution from 1G to 5G mobile network, applications, different research groups, their work, and the key features of 5G. It is not just a mobile broadband network, different from all the previous mobile network generations; it offers services like IoT, V2X, and Industry 4.0. This paper covers a detailed survey from multiple authors on different technologies in 5G, such as massive MIMO, Non-Orthogonal Multiple Access (NOMA), millimeter wave, small cell, MEC (Mobile Edge Computing), beamforming, optimization, and machine learning in 5G. After each section, a tabular comparison covers all the state-of-the-research held in these technologies. This survey also shows the importance of these newly added technologies and building a flexible, scalable, and reliable 5G network.

9. Future Findings

This article covers a detailed survey on the 5G mobile network and its features. These features make 5G more reliable, scalable, efficient at affordable rates. As discussed in the above sections, numerous technical challenges originate while implementing those features or providing services over a 5G mobile network. So, for future research directions, the research community can overcome these challenges while implementing these technologies (MIMO, NOMA, small cell, mmWave, beam-forming, MEC) over a 5G network. 5G communication will bring new improvements over the existing systems. Still, the current solutions cannot fulfill the autonomous system and future intelligence engineering requirements after a decade. There is no matter of discussion that 5G will provide better QoS and new features than 4G. But there is always room for improvement as the considerable growth of centralized data and autonomous industry 5G wireless networks will not be capable of fulfilling their demands in the future. So, we need to move on new wireless network technology that is named 6G. 6G wireless network will bring new heights in mobile generations, as it includes (i) massive human-to-machine communication, (ii) ubiquitous connectivity between the local device and cloud server, (iii) creation of data fusion technology for various mixed reality experiences and multiverps maps. (iv) Focus on sensing and actuation to control the network of the entire world. The 6G mobile network will offer new services with some other technologies; these services are 3D mapping, reality devices, smart homes, smart wearable, autonomous vehicles, artificial intelligence, and sense. It is expected that 6G will provide ultra-long-range communication with a very low latency of 1 ms. The per-user bit rate in a 6G wireless network will be approximately 1 Tbps, and it will also provide wireless communication, which is 1000 times faster than 5G networks.

Acknowledgments

Author contributions.

Conceptualization: R.D., I.Y., G.C., P.L. data gathering: R.D., G.C., P.L, I.Y. funding acquisition: I.Y. investigation: I.Y., G.C., G.P. methodology: R.D., I.Y., G.C., P.L., G.P., survey: I.Y., G.C., P.L, G.P., R.D. supervision: G.C., I.Y., G.P. validation: I.Y., G.P. visualization: R.D., I.Y., G.C., P.L. writing, original draft: R.D., I.Y., G.C., P.L., G.P. writing, review, and editing: I.Y., G.C., G.P. All authors have read and agreed to the published version of the manuscript.

This paper was supported by Soonchunhyang University.

Institutional Review Board Statement

Informed consent statement, data availability statement, conflicts of interest.

The authors declare no conflict of interest.

Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations.

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Ideas Made to Matter

5G, explained

Feb 13, 2020

Most Americans have yet to use a 5G-connected device, but the next-generation cellular network is already generating buzz. Ads and headlines tout a 5G revolution that will change the way people live and work, through unprecedented digital speeds, reduced lag, and better connectivity for a broader range of devices. Some say it’ll spur a fourth industrial revolution.

With experts expecting 5G to become widely available in the next few years, the full business impact of the network has yet to be seen. What’s clear is that it’s ripe with opportunity for fields as varied as entertainment, manufacturing, health care, and retail. Successful enterprises will tap 5G to boost “internet of things” applications, virtual and augmented reality, and larger-scale robot and drone deployments.

“What does this mean? It depends who you are,” said MIT electrical engineering and computer science professor Muriel Médard . For users, which includes most businesses, “it’s likely you’ll get a rich set of offerings, and you’ll get better coverage,” said Médard, who leads the Network Coding and Reliable Communications Group at MIT’s Research Laboratory for Electronics.

As the first 5G symbols begin to pop up on cellphones, it’s time for businesses to think about how to harness the possibilities. “If you’re a business leader looking to use this network to provide some new services for customers, or if [you] would like to create some new value that’s not possible today … all of this is possible with 5G,” said Athul Prasad, a student in the MIT Sloan Fellows program who is on sabbatical from Nokia, where he was the head of 5G business modeling and analytics.

Companies that embrace 5G early stand to gain, said Diego Fernandez Bardera, a principal consultant at Ericsson who focuses on 5G and the internet of things. Some 73% of 4G first-movers grew their market share after their 4G launch, and a 5G first-mover likewise will benefit, said Bardera, a graduate of the MIT Sloan Fellows program. “I urge organizations and the whole ecosystem, from industry partners to universities, to have discussions across business and operational domains to better understand how 5G will transform their industries.”  

Here’s what businesses need to know to set themselves on a course for 5G success:

From 1G to 5G

5G is the fifth-generation cellular network, as formally defined by global standards agencies . New networks have emerged roughly every 10 years since 1980, when 1G came on the scene with large cellphones that only made phone calls. Later, 2G introduced messaging, 3G brought access to the internet, and 4G, which emerged around 2009, brought a leap in data download speeds, allowing users to do things like stream movies on mobile devices.

The official definition of 5G specifies higher speeds and lower latency — the lag time between when a device asks for information and when it receives it, Médard explained. The network will use higher-frequency radio waves in addition to the range of frequencies already used, and will work with smaller, more closely distributed wireless access points instead of large, dispersed cell towers.

5G is also expected to include a suite of hybrid technologies that will facilitate seamless transitions between different Wi-Fi networks or from cellular networks to Wi-Fi, and allow networks to more easily take advantage of unused extra bandwidth.

5G should allow for higher connectivity — that is, more devices connected to a network — and significantly higher download speeds. Speed isn’t the only improvement, though.

Consistency will be key, Médard said. 5G will allow small, consistent amounts of data to be accessed on a regular basis. “If you have needs such as streaming, gaming, even more if you go to something like virtual reality, you don't need a huge amount of data delivered to you at once,” she said. “What you may need is a more modest amount, but reliably delivered, and delivered with shorter delays.”

Experts expect 20 billion connected IoT devices by 2023.

Augmented reality — overlaying virtual information over a live view of the world — and virtual reality both need reliable, low latency networks to be effective, which makes them prime use cases for 5G. (Beyond being inconvenient, high latency while using virtual reality devices can cause motion sickness.)

Shorter range radio waves and cell towers that cover smaller areas will also improve location tracking . That opens the way for businesses to use geolocation to their competitive advantage, though some advocates have pointed out it also raises privacy concerns .

Speedier and more reliable communication and reduced lag times will enable new IoT use cases that are more widely and easily deployed, according to industry experts. While some companies are already using connected sensors in the field, 5G is expected to bring the internet of things into the mainstream with new uses and massive connectivity.

Experts expect 20 billion connected IoT devices by 2023 — representing millions of usually low-cost devices with long battery lives that can transmit non-delay-sensitive data, Bardera said. 5G will also allow what’s called ultra reliable and low latency connectivity, which is required for critical applications like traffic safety, remote surgery, or precise positioning for industrial uses.

For firms, opportunities abound

Industries considered most likely to be transformed by 5G include media and entertainment, manufacturing, retail, health care, hospitality, finance, and shipping and transportation. And the new network stands to enable or improve technologies as far-ranging as holograms, artificial intelligence and machine learning, industrial robots, drones, and smart cities, buildings, and homes.

“When you think about 5G you should think, ‘Well, what doesn’t really work on 4G?'” said Nicola Palmer, senior VP of technology and product development at Verizon, who spoke on a 5G panel at the 2019 MIT Platform Summit .

For example, computer vision, augmented reality, and virtual reality for health care don’t work on 4G networks, she noted. “How do you really tie into those capabilities in a way that creates value for enterprise and consumers alike?” 5G is a key part of the answer. Bardera said organizations approaching 5G should first assess its potential in relation to their specific industry, business, and market. From there they can select and prioritize the most suitable use cases in terms of business impact, time to market, and investment required.

Some industries are already test-driving 5G internet of things ideas for business purposes. For example, in the oil and gas industry, a Houston telecommunications company recently partnered with Nokia to bid on bringing 5G to several oil and gas fields. Other companies are developing “smart harbors” in Germany and China that include automated ship-to-shore crane lifts and sensors with real-time traffic monitoring. A mobile company in South Korea is at work building a 5G infrastructure for a smart traffic system in Seoul. Ericsson has embraced new industrial IoT uses, such as increased assembly and testing efficiency at a plant in Estonia through the use of augmented and virtual reality, Bardera said. And Nokia and ARENA2036 have announced an automotive research partnership at a factory in Germany to validate 5G use cases. 

5G will also make it easier to upgrade facilities or establish new plants. “Factories tend to have a lot of wires, which limits their mobility,” said Prasad. Wired factories are costly to upgrade, he said, but those costs will diminish with wireless sensors.

In entertainment, a 2019 Deloitte Mobile Trends survey predicted 5G could have a large impact on digital entertainment, especially among younger consumers, who said they plan to use 5G to consume media with virtual and augmented reality and that they’d likely play more mobile video games using 5G. Virtual and augmented reality with 5G can be used to train surgeons, truck drivers , and other employees in high-risk professions, as well as for videoconferencing, improved online and physical retail experiences, tourism, and education.

And on the farm, 5G innovations include sensors that control a smart feeding system and open curtains depending on the weather. And a herd of dairy cows in rural England were given 5G-connected devices on their collars that connected to a robotic milking system.

One cutting-edge technology that won’t rely on 5G is autonomous vehicles, according to MIT senior lecturer Nick Pudar,  the former director of corporate strategy at General Motors Co. Pudar said vehicles must be able to make driving decisions without relying on external connections, which may or may not be available. But 5G connectivity will allow vehicles to collect data about car maintenance, road conditions, weather and traffic that can lead to higher quality maps and congestion planning, he said. 

When to expect 5G

A 5G forecast released last year predicted 5G connections around the world will grow from 10 million in 2019 to more than 1 billion in 2023.

5G is already available in limited areas in the United States and worldwide. Experts estimate that 77 service providers worldwide launched 5G commercially by the end of 2019, Bardera said, with coverage and availability varying by country or region. In South Korea, the world’s largest 5G market, there are more than 3 million subscribers, he said.

AT&T, Sprint, T-Mobile and Verizon, the four largest U.S. carriers, have all rolled out some   5G service to consumers, mostly in select areas of certain cities, and all of the carriers promise more is on the way.

5G devices are slowly coming out, with expensive 5G cellphones for sale. Industry experts predict that Apple could introduce its first 5G-capable phones in 2020. Major Android equipment manufacturers have announced flagship 5G mobile devices, with many already shipping.

73% of 4G first-movers grew their market share after their 4G launch.

5G also requires infrastructure, including the installation of new wireless access points that are closer together. A host of companies are also working on providing 5G hardware and equipment. The U.S. government has cited concerns that Chinese technology company Huawei, which is providing 5G infrastructure in several countries, could give the Chinese government a “back door” to the networks and access to data and information. The United States has lobbied other countries not to use Huawei, though the United Kingdom recently agreed to have the company build part of its 5G network.

There are other concerns, perhaps perceived, to overcome. Critics are raising alarms about radio waves causing cancer and other health problems. Some cities have resisted the installation of 5G poles, and politicians have introduced resolutions urging formal study into its health implications. But a widely cited study that says 5G might be harmful has been debunked .

5G will boost security in some ways, with encrypted data, segmented networks, and user authentication, but also has security vulnerabilities , including potential spying and attacks. The increase in connected devices also creates more targets and attacks on vital connected systems could become more chaotic and consequential.

Experts are estimating a widespread rollout between 2021 and 2024. “I think it’s dependent on forward-looking industries to lean in,” Palmer said. “The examples are out there … leaning in will dictate how fast it happens.”

Prasad agreed. “I think that by 2021 that's kind of the timeline where we are thinking that it would be getting more and more wide-scale,” he said.

What’s certain is that 5G is on the way — with 6G already waiting in the wings — which means businesses should start preparing for what it might bring. Just as Uber, Netflix, and Spotify were enabled by 4G’s use of data and streaming, new or established companies could prove to be the winners in a 5G world, according to Prasad.

“It’s kind of a low-risk investment,” Prasad said, pointing out that the mobile ecosystem enabled by 4G created around $4 trillion in new economic value. “I think 5G could create even more value.”

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The WIRED Guide to 5G

The future depends on connectivity. From artificial intelligence and self-driving cars , to telemedicine and mixed reality, to as yet undreamed technologies, all the things we hope will make our lives easier, safer, and healthier require high-speed, always-on internet connections. To keep up with the demand, the mobile industry introduced 5G —so named because it's the fifth generation of wireless networking technology.

5G brings faster speeds of up to 10 gigabits per second (Gbps) to your phone. That's fast enough to download a 4K movie in 25 seconds. But 5G is not just about faster connections. It also delivers lower latency and allows for more devices to be connected simultaneously.

As the fifth generation of cellular networks, 5G is a global wireless standard. All cellular networks send encoded data through radio waves. Radio waves have different frequencies and are divided into bands. Previous generations, like 4G, operated on low- and mid-band frequencies, but 5G can operate on low-, mid-, and high-band (also known as millimeter wave) frequencies. Lower frequencies can travel farther and penetrate through obstacles but offer relatively low speeds, while higher frequencies are much faster but have a limited range and struggle to pass through objects.

While 5G opens up a swathe of unused radio frequencies at the high end of the spectrum, it also encompasses new technologies and techniques for combining chunks of spectrum that are already in use. At the low end, 5G looks and feels very much like 4G.

Carriers have been building their 5G networks for a few years now, but they have adopted different approaches. All the carriers began by building 5G atop their existing networks, which provided lots of connectivity, but not at the high speeds associated with 5G. More recently, they have started building out new high-band 5G networks, but these are largely confined to cities or specific venues within cities. You can get a broad overview by using Ookla’s 5G map .

Verizon offers low-band 5G across the country, labeled as 5G Nationwide on its coverage map . Verizon offers mid-band 5G in many urban areas and high-band 5G in many cities, but the mid- and high-band coverage are lumped together and labeled 5G Ultra Wideband or 5G UW.

AT&T also offers low-band 5G coverage across much of the country and mid-band coverage in some cities, both labeled simply as 5G on its coverage map . AT&T’s high-band 5G is currently limited to a selection of venues, like stadiums, and is labeled as 5G+. Early in its 5G efforts, AT&T marketed its spiffed-up LTE network as "5G E" and was rebuked by the National Advertising Review Board for misleading customers.

T-Mobile offers low-band 5G across the country, labeled as 5G Extended Range on its coverage map . Its mid- and high-band 5G is labeled as 5G Ultra Capacity.

Ultimately, 5G availability and speeds are variable because 5G service is offered in three bands. Low-band, which generally operates below 1 GHz, can reach speeds of 250 Mbps. The trade-off for low-band’s comparatively slower speeds is a broad reach, which means carriers can leave more distance between towers using this kind of equipment.

Analysts call the mid-band of the 5G spectrum the sweet spot, as it has a broad geographic reach and is faster than low-band. Mid-band operates between 1 and 6 GHz and can achieve speeds up to 1 Gbps.

But to reach the top speeds associated with 5G, carriers need millimeter-wave (or mmWave) technology, which takes advantage of the high end of the wireless spectrum, operating at 20 GHz and up. mmWave can enable multi-gig speeds, but millimeter-wave signals are less reliable over long distances and easily disrupted by obstacles like trees, people, and even rain. To make it practical for mobile use, carriers must deploy huge numbers of small access points in cities, instead of relying on a few big cell towers as they do today.

Figuring out whether 5G is available for you , and in what form, requires a bit of detective work, but you will also need a device capable of handling a 5G signal.

Anyone wishing to take advantage of these new 5G networks needs a capable device. Most major phone makers offer 5G handsets now, but, as we’ve seen, 5G is an umbrella term. All 5G phones have low- and mid-band support (often labeled “sub-6,” as they operate at frequencies of 6 GHz and lower), but not all 5G phones are capable of high-band connections. If you want a smartphone that can take advantage of high-band (mmWave) networks, look for mmWave support.

You can find mmWave support in high-end phones like Apple's iPhone 14 Pro , Google Pixel 7 Pro , and the Samsung Galaxy S22 in the US. It’s worth noting that these same models are often sold without mmWave support in other countries.

Much of the buzz around 5G is focused on its potential. Since smartphones connected to 4G LTE can already stream high-quality video, you may be wondering what 5G brings to the table for regular folks. Aside from faster download speeds, lower latency benefits multiplayer and cloud gaming by boosting responsiveness. And 5G's higher capacity for multiple devices to be connected without issue also helps to keep us all online when we are part of a crowd, whether it’s a packed concert or a football game.

The stability and speed of 5G also promise improvements for driverless cars, remote-piloting drones, and anywhere else where response time is crucial. While tangible benefits today are limited, there is enormous potential for more cloud computing services, augmented reality experiences, and whatever comes next. But a real killer 5G app for consumers remains elusive. 

The US has been keen to claim a leadership role in worldwide 5G deployment, but so far it hasn’t fully succeeded. China-based Huawei is the world’s leading maker of 5G network equipment, and while its equipment is deployed widely, the company has faced scrutiny and even bans from Western nations for its alleged ties to the Chinese government. Other companies that make 5G equipment, like Nokia, Ericsson, and Samsung— none of which, notably, are headquartered in the US —may have benefited from the bans.

From a speed perspective, the US doesn’t appear in the top 15 nations, according to the UK-based research firm Opensignal , which found that South Korea had the top 5G download speed at 432.7 Mbps, followed by Malaysia, Sweden, Bulgaria, and the United Arab Emirates. Where the US did score highly was in 5G availability, with a score of 25.2 percent, meaning users spent over one-quarter of their time with an active 5G connection—an impressive result for a country the size of the US, and a sign that the rollout is gathering pace.

By Carlton Reid

By Emily Mullin

By Andy Greenberg

By Scott Gilbertson

The first generation of mobile wireless networks, built in the late 1970s and 1980s, was analog. Voices were carried over radio waves unencrypted , and anyone could listen in on conversations using off-the-shelf components. The second generation, built in the 1990s, was digital—which made it possible to encrypt calls, make more efficient use of the wireless spectrum, and deliver data transfers on par with dialup internet or, later, early DSL services. The third generation gave digital networks a bandwidth boost and ushered in the smartphone revolution.

(The wireless spectrum refers to the entire range of radio wave frequencies, from the lowest frequencies to the highest. The US Federal Communications Commission, or FCC, regulates who can use which ranges, or “bands,” of frequencies and for what purposes, to prevent users from interfering with each other’s signals. Mobile networks have traditionally relied mostly on low- and mid-band frequencies that can easily cover large distances and travel through walls. But those are now so crowded that carriers have turned to the higher end of the radio spectrum.)

The first 3G networks were built in the early 2000s, but they were slow to spread across the US. It's easy to forget that when the original iPhone was released in 2007, it didn't even support full 3G speeds, let alone 4G. At the time, Finnish company Nokia was still the world’s largest handset manufacturer, thanks in large part to Europe’s leadership in the deployment and adoption of 2G. Meanwhile, Japan was well ahead of the US in both 3G coverage and mobile internet use.

But not long after the first 3G-capable iPhones began sliding into pockets in July 2008, the US app economy started in earnest. Apple had just launched the App Store that month, and the first phones using Google's Android operating system started shipping in the US a few months later. Soon smartphones, once seen as luxury items, were considered necessities, as Apple and Google popularized the gadgets and Facebook gave people a reason to stay glued to their devices. Pushed by Apple and Google and apps like Facebook, the US led the way in shifting to 4G, leading to huge job and innovation growth as carriers expanded and upgraded their networks. Meanwhile, Nokia and Japanese handset makers lost market share at home and abroad as US companies set the agenda for the app economy.

There's more to 5G than mobile phones; 5G technologies will also serve a great many devices in near real time. That will be crucial as the number of internet-connected cars, environmental sensors, thermostats, and other gadgets accelerates in the coming years.

5G is expected to help autonomous cars communicate not only with one another—a kind of “Hey, on your left!” set of exchanges—but also, someday, with roads, lights, parking meters, and signals. And 5G’s low latency promises to better enable remote surgeries, allowing physicians in one location to manipulate network-connected surgical instruments thousands of miles away (a capability the pandemic has made even more desirable). Medical providers may also be able to rely on 5G to rapidly transmit high-resolution images for use in diagnosis and treatment.

Manufacturers can use 5G networks to monitor production lines remotely and maintain videofeeds of their factory floors, or to feed data to workers wearing augmented reality glasses. Some companies are licensing their own bit of 5G spectrum and are replacing Wi-Fi networks with private 5G networks .

Even though 5G remains far from universally available, the telecom industry is already looking forward to the next big thing : 6G—the technology that will take advantage of areas of the wireless spectrum above 100 GHz.

• Why Airlines Are Fighting the 5G Rollout Airline companies want more time to prepare for the potential impact of 5G frequencies on crucial safety equipment.
• Why Almost No One Is Getting the Fastest Form of 5G A new report shows that US mobile customers are tapping into the technology’s speediest networks less than 1 percent of the time.
• Choosing the Wrong Lane in the Race to 5G FCC Chair Jessica Rosenworcel argues that by focusing on millimeter-wave technology, the US is taking the wrong path to 5G.
• How the Sprint/T-Mobile Merger changes the mobile landscape T-Mobile gained valuable 5G wireless spectrum as part of the deal.

Last updated December 2022.

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Essay on 5G Technology

Students are often asked to write an essay on 5G Technology in their schools and colleges. And if you’re also looking for the same, we have created 100-word, 250-word, and 500-word essays on the topic.

Let’s take a look…

100 Words Essay on 5G Technology

Introduction to 5g technology.

5G stands for fifth-generation wireless technology. It’s the latest innovation in mobile internet, promising faster speeds and more reliable connections than previous generations like 4G and 3G.

Benefits of 5G

5G can download and upload data much faster. This means quicker access to websites, smoother streaming of videos, and less lag in games. It also supports more devices, which is crucial as more gadgets become internet-enabled.

Applications of 5G

5G can revolutionize many sectors. In healthcare, it can support remote patient monitoring. In transport, it can enable self-driving cars. It can even make smart cities more efficient.

Challenges of 5G

Despite its benefits, 5G faces challenges. It requires new infrastructure, which can be expensive. There are also concerns about cybersecurity, as more devices will be connected to the internet.

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• 10 Lines on 5G Technology

250 Words Essay on 5G Technology

5G, or fifth generation technology, is the latest iteration in the evolution of wireless technologies. It promises to revolutionize the way we interact with technology, offering unprecedented speeds, low latency, and the ability to connect a multitude of devices simultaneously.

Unleashing Unprecedented Speeds

5G’s most touted feature is its speed. It is projected to offer peak data rates up to 20 Gbps, which is about 100 times faster than 4G. This speed will enable seamless streaming of high-definition content, and make downloading and uploading large files a breeze.

Reducing Latency

Beyond speed, 5G also aims to reduce latency, or the delay before a transfer of data begins following an instruction for its transfer. Lower latency will enhance the user experience in real-time applications such as online gaming, video conferencing, and autonomous driving.

Enabling the Internet of Things (IoT)

Perhaps one of the most significant impacts of 5G will be its role in enabling the Internet of Things. By allowing a vast number of devices to connect and communicate simultaneously, 5G will facilitate the growth of smart homes, smart cities, and industrial IoT.

While 5G technology is filled with promise, it also presents challenges, such as infrastructure costs and privacy concerns. However, if these can be overcome, the potential benefits of 5G could usher in a new era of technological advancement. In the end, 5G represents not just an upgrade in speed, but a transformation in the way we live and interact with technology.

500 Words Essay on 5G Technology

5G, the fifth generation of wireless communication, represents a significant leap forward in the realm of mobile technology. Unlike its predecessors, 5G offers far more than just faster download and upload speeds. It promises a new digital ecosystem teeming with unprecedented connectivity, ultra-low latency, and massive network capacity.

Key Features of 5G

One of the defining features of 5G is its ability to support a massive number of connected devices. IoT (Internet of Things) devices, from smart home appliances to autonomous vehicles, will be able to communicate seamlessly, fostering a more integrated digital society.

5G also boasts ultra-low latency, the delay between the sending and receiving of information. This is critical for applications requiring real-time responses, such as remote surgeries, autonomous driving, and real-time gaming.

Furthermore, 5G networks have a high-frequency millimeter-wave spectrum, allowing for faster data transmission and accommodating more users without network congestion.

Implications of 5G Technology

The implications of 5G extend far beyond individual consumer benefits. It’s set to revolutionize industries by enabling new applications and business models.

In healthcare, 5G could make remote patient monitoring and telemedicine more effective, reducing the need for physical hospital visits. In the automotive industry, the ultra-low latency of 5G could make autonomous vehicles safer and more efficient.

Moreover, 5G is expected to spur innovation in areas like virtual and augmented reality, AI, and machine learning, opening up new avenues for technological advancement.

Challenges and Concerns

Despite its potential, the deployment of 5G also presents significant challenges. The high-frequency spectrum of 5G, while enabling faster speeds, has a shorter range and is more susceptible to physical obstructions, necessitating the installation of numerous small cells.

Privacy and security are other major concerns. With more devices connected, the risk of cyber-attacks increases, demanding robust security measures.

Lastly, there are concerns about the potential health impacts of 5G radiation, although current research indicates that exposure levels are within international guidelines.

5G technology, with its promise of high-speed connectivity, low latency, and capacity to connect a massive number of devices, is set to transform our digital landscape. It holds the potential to revolutionize industries and spur technological innovation. However, its successful implementation hinges on overcoming significant challenges, including infrastructure requirements, privacy, and security concerns. As we stand on the brink of this new era, it is crucial to navigate these challenges wisely to harness the full potential of 5G.

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essay about 5g technology

The Technological Marvel: A Comprehensive Analysis of 5G Technology

The advent of 5G technology represents a significant milestone in the evolution of wireless communication. This essay aims to provide a detailed and technical exploration of 5G technology, covering its key components, architecture, benefits, and potential applications.

Introduction:

The fifth generation of wireless technology, commonly known as 5G, promises to revolutionize the way we connect and communicate. Unlike its predecessors, 5G is not merely an incremental improvement but rather a paradigm shift in the realm of wireless networks. This essay will delve into the technical intricacies that make 5G a cutting-edge technology.

Key Components of 5G Technology:

• One of the defining features of 5G is its use of millimeter-wave frequencies, ranging from 24 GHz to 100 GHz. These high-frequency bands enable significantly higher data transfer rates compared to previous generations.
• 5G leverages Massive MIMO technology, which involves the use of a large number of antennas at both the transmitter and receiver ends. This spatial diversity enhances data throughput, reliability, and efficiency.
• Beamforming is a technique used in 5G to focus the transmission of signals in specific directions, creating more efficient communication links. This improves network capacity and coverage.
• 5G introduces the concept of network slicing, allowing the creation of virtualized, isolated networks tailored for specific applications. This enables the coexistence of diverse services with distinct requirements on a single physical infrastructure.
• The integration of edge computing in 5G architecture reduces latency by processing data closer to the end-user. This is particularly crucial for applications such as augmented reality (AR), virtual reality (VR), and autonomous vehicles.

Architecture of 5G Networks:

• The RAN is a critical component of 5G architecture, comprising base stations equipped with massive MIMO antennas. These base stations communicate with user devices and facilitate the transmission of data between devices and the core network.
• The 5G core network is designed to be more flexible and scalable than its predecessors. It incorporates technologies like network function virtualization (NFV) and software-defined networking (SDN) to enable dynamic allocation of resources and efficient network management.
• 5G integrates cloud services seamlessly, enabling a distributed and scalable network architecture. This facilitates the deployment of services closer to the edge, reducing latency and enhancing user experience.

Benefits of 5G Technology:

• 5G offers significantly higher data transfer rates, reaching multiple gigabits per second. This ensures faster download and upload speeds, enabling applications that demand massive data throughput.
• With reduced latency, 5G supports real-time applications such as augmented reality, virtual reality, and autonomous vehicles. This low latency is achieved through the combination of edge computing and optimized network architecture.
• 5G is designed to accommodate a massive number of connected devices, making it suitable for the Internet of Things (IoT) applications. This includes smart cities, smart homes, and industrial IoT.
• The use of advanced technologies such as beamforming and dynamic resource allocation enhances energy efficiency in 5G networks. This is crucial for sustainability and reducing the environmental impact of wireless communication.

Potential Applications of 5G:

• 5G provides a significant boost in data rates, making it ideal for delivering high-quality multimedia content, immersive gaming experiences, and other data-intensive applications on mobile devices.
• Applications that demand ultra-low latency, such as remote surgery, autonomous vehicles, and industrial automation, can benefit from the URLLC capabilities of 5G.
• 5G's ability to connect a massive number of devices simultaneously makes it suitable for applications involving a vast network of sensors and devices, such as smart grids and agricultural monitoring systems.

Challenges and Future Developments:

While 5G brings unprecedented capabilities, challenges such as security concerns, spectrum management, and infrastructure deployment remain. Future developments may involve the evolution towards 6G, exploring even higher frequencies, more advanced technologies, and novel use cases.

Conclusion:

In conclusion, 5G technology stands at the forefront of innovation in wireless communication, offering higher speeds, lower latency, and enhanced connectivity. The technical components and architectural advancements discussed in this essay underscore the transformative potential of 5G across various industries and applications, paving the way for a more connected and technologically advanced future.

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How to accelerate the world into the 5G era

The innovative yet consumer-centric groundwork enabling 5G smartphones to empower users en masse.

Provided by vivo

Demand for 5G smartphones is reaching an all-time high

In 2021, consumers and institutions alike are fast-tracking a digital revolution in an unprecedented era of social distancing and remote work—a trend that may continue long after the pandemic subsides.

The time is ripe for many commercialized products and services to ride the wave of unparalleled high-speed connectivity and minimal latency enabled by 5G. Yet, the technology at the forefront of them all is without a doubt the smartphone. By combining mobile telephone and computing functions within a singular multi-purpose device, smartphones have brought about a profound scale of mobility and accessibility with one-stop services that empower consumers across every aspect of their daily lives.

Some may look back fondly on the good old days of the mobile phone, when voice calls and text messaging were all we had access to, in the absence of addictive social media platforms and the seemingly endless barrage of notifications we receive nowadays. Nonetheless, the instantaneous connectivity of ever-improving mobile networks and increasingly diverse applications of smartphones will undeniably continue to bring value to users.

According to a forecast by vivo, one of the leading smartphone makers, demand for 5G devices is catching up to the entirety of the smartphone market as researchers recorded exponential growth between 2020 and 2021.

Another report, published by Gartner, showed that the worldwide demand for smartphones with 5G capabilities more than doubled this year. “In 2020, consumers reduced spending on smartphones, but the availability of new products will see users drive significant uptick in demand in 2021. Lower-end 5G smartphones, which are becoming more prevalent outside China, are poised to drive more momentum for 5G smartphones in 2021 across all regions,” said Anshul Gupta, senior research director at Gartner.

How did we get to where we are today, and how did smartphone brands take us here? 

Defining the fifth generation

5G is the latest global wireless standard, otherwise known as the 5th generation of cellular mobile communication technology. Compared to 4G LTE technology, 5G increases flux density a hundredfold and connection density tenfold. This allows for a new kind of digital infrastructure that can connect virtually everything and everyone via peak data transmission speeds with minimal latency to provide a uniform experience to us all, culminating in higher efficiency and optimized performance to empower new user experiences.

Hundreds of thousands of industries are becoming integrated, owing to the reliable and streamlined network between machines, devices, and other digital objects. With many creative applications ranging from augmented reality/virtual reality experiences to vehicle-to-everything driverless cars and many more, 5G will provide humankind with the foundation to establish smart cities with comprehensive internet-of-things technologies that can efficiently restructure our lived environments and redefine our everyday lifestyles.

It goes without saying that 5G can facilitate limitless applications, on both industrial and consumer levels. For tech-savvy individuals accustomed to heavy device usage loads, 5G will be game-changing by elevating their collective digital devices into powerful, cloud-synced gateways capable of tapping into the most resource-intensive applications and data streams. Many industries are currently undergoing paradigm shifts as enterprises and countries race to propel society into the next phase of technological transformation.

Gearing up for the 5G race – a deep dive with vivo

The 5G technical standard was formed by a series of innovative R&D efforts led by companies such as vivo. The 5G products or services consumers are presented with today are actually a refined conglomeration of technologies formulated by the 3rd Generation Partnership Project (3GPP), a consortium of international telecom standards organizations that provide a stable platform for collaboration.

As the entire world becomes familiar with the limitless possibilities of contemporary mobile communications technology, consumers are looking to arm themselves with devices that contain cutting-edge capabilities in order to complement their connected and fast-paced daily lifestyles.

Corporations and governments are both racing to gear up in preparation for the new digital gold rush. Unbeknownst to many, battles are fought and alliances are formed every day as companies cannibalize each other in the race to hold the most patents for 5G technologies.

Vivo, one of the top players, has participated in the 3GPP 5G standard formulation for over five years. As one of many companies that set their sights on 5G technology, vivo established special 5G task forces back in December 2016 across Beijing and Shenzhen, China. One month later, vivo made its debut at the 2017 3GPP meeting. Since then, vivo has submitted over 5,000 5G proposals to the 3GPP, leading to 15 technical features and getting three technical projects approved. With more than 100 global standard experts staffed at its communication research institute, vivo now holds over 3,000 patents for 5G inventions.

User-oriented innovation

As a leading smartphone company with in-depth R&D capabilities, vivo is dedicated to accelerating the empowerment of consumers en masse in this new era by designing cutting-edge 5G smartphones that are available at every price point. Having amassed over 400 million users worldwide, vivo has a deep understanding of evolving consumer demands and strives to bridge users with the digital world by becoming one of the leading contributors to 5G technology in the industry.

“The main gateway for consumers to indulge in the new digital era must be the most accessible, portable, cost-effective, and readily available digital device of them all: the smartphone. A leader in both smartphone manufacturing and 5G connectivity, vivo has been designing a diverse lineup of products that are ready for the next generation of connectivity to bring joy to users worldwide at modest price points,” says Rakesh Tamrakar, 5G standards expert at vivo. 

Tamrakar has 20 years of experience in the mobile communications industry. He is one of the lead delegates representing vivo in the 3GPP, holds numerous patents, and has chaired multiple 3GPP RAN1 sessions (which specify the physical layer of radio interfaces) that led to the successful standardization of MIMO, NR on unlicensed spectrum technologies. Multiple Input Multiple Output (MIMO) is a key 5G technology that increases throughput and signal-to-noise ratio, while NR is a new radio interface and radio access technology for cellular networks. He has authored and contributed numerous technical papers on the subject of 3GPP RAN1 in 3G, 4G, and 5G standards.

“Brought to life by our strong R&D network across nine innovation centers and supported by research teams across the globe, vivo knows consumers best within the industry. We focus on innovations in hardware design and the software ecosystem to improve terminal performance and user experiences. Putting end users at the center of everything we do, vivo invests heavily into 5G connectivity to reach the stage of product realization and getting this technology into the hands of consumers,” he adds.

5G research, standardization, and industrialization by vivo

Vivo’s unique user-oriented innovation is the genesis behind its numerous patented contributions to 5G standards, many of which have been universally acclaimed at the 3GPP meeting and are currently already being adapted for everyday smartphone users.

One of vivo’s most notable contributions includes the standardization and performance enhancement of Rel-17 multi-SIM technology. Previously, an incoming voice call from one competing 5G SIM card would interrupt the data flow of the other, resulting in abysmal performance as one would cancel the other. Having discovered early on that consumers had a preference for 5G smartphones with dual-SIM card slots for greater flexibility in different usage scenarios, vivo researchers successfully sought to negate the clash, leading to the existence of multi-SIM 5G smartphones on the market today.  

The initial implementation of 5G technology was initially found to be quite resource-draining compared to devices running on 4G. However, consumers had grown accustomed to the substantial usage time allowed by previous smartphones.

Always innovating with the user in mind, the Rel-16 terminal power-saving technology patented by vivo manages to simplify terminal actions. It lowers normal energy consumption by creating a new “dozing” state, allowing the device software to become inactive while the hardware becomes idle. 5G smartphones can now intelligently catch every chance to take a rest, thereby prolonging battery life.

Additionally, vivo underwent algorithm and system optimization to facilitate this technology, combined with 120-watt fast charging to ensure complete user satisfaction with their devices. Select vivo smartphones are housed with a superconducting carbon fiber liquid cooling system to prevent device overheating, which is especially prevalent during intensive multimedia entertainment or e-sports usage scenarios.

Another issue raised by 5G technology is the increasing number of antennas and components installed inside a smartphone. However, users are relentless in their pursuit for ultra-thin smartphones encased in sleek metallic exteriors. Never one to disappoint, vivo’s proprietary 3D stack design uniquely encases all of this industry-leading technology to allow new 5G smartphones to be even slimmer than its 4G predecessors.

6G visionary

As 5G commercial networks are gradually deployed around the world and progressively advanced devices increasingly permeate every aspect of our livelihoods, thought leaders of the mobile industry are already looking forward to its next generation: 6G.

Vivo is part of a select few that hold the extensive expertise and in-depth understanding of consumer needs in order to turn this vision into a reality. Along with leading companies, research groups, and academic institutions, this combined elite collective is expected to reach a consensus on the ideation and requirements for this future generation of connectivity. To kickstart this exciting new era, the vivo Communications Research Institute (VCRI) released two white papers in late 2020 that break down the facets of 6G technology. Providing a diverse set of hypothetical scenarios and case studies, vivo communication standard experts have analyzed how the sixth generation will embody much more than technological transformation as it merges our physical and digital worlds.

“Currently, mobile infrastructure is still relatively isolated from the physical world, existing solely as an auxiliary tool for consumer usage. An extreme degree of seamlessness will be required to dynamically connect our physical surrounding with the omnipresent digital systems. In 2030 and beyond, 6G standard technologies will begin to foster a ubiquitous, sophisticated, real-time, and fully integrated digital world. This new realm will revolutionize thousands of industries with an extraordinary variety of applications to result in an efficient, sustainable, and eco-friendly future world,” says Tamrakar.  

6G communication systems will comprise many device terminals to realize the agile perception and accurate control between digital systems with our physical domain; this is comparable to the nerve endings that perceive essential information from every inch of the human body for our central nervous system to take responsive measures. As such, a large number of harmoniously connected and intelligent terminals in the form of smartphones or wearable devices will be fundamentally required in order for the entire IoE (internet-of-everything) system to be effective. To that end, vivo has launched a smartwatch, wireless earbuds, and Jovi AI assistant to introduce users to its own flourishing digital ecosystem.

Notwithstanding all of this exhaustive groundwork laid by technology companies, the 5G race and the 6G marathon are far from over. Nonetheless, affordable smartphones with innovative features will continue to act as the interface for everyday users to engage with the all-encompassing network infrastructure, to accelerate the impending intelligent transformation of society.

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News from the Columbia Climate School

The Coming 5G Revolution: How Will It Affect the Environment?

COVID-19 has made one thing crystal clear: Society needs the Internet to function. During the pandemic, the Internet has been critical for buying groceries, working, educating children, getting medical care, accessing news and being entertained. The health and safety of the population depends on the reliability of the network. Since January, the daily broadband use of individual Americans has increased 3 gigabytes —enough capacity to browse the Internet for 90 hours or watch HD movies for an hour. All this demand for fast, reliable and diversified communication has increased pressure on countries to quickly adopt 5G—the latest generation of digital technology.

The promise of 5G

Approximately every ten years, new wireless mobile technology emerges that improves on the previous generation. 1G, which came out in the 1980s, supported only voice calls. 2G, born in the 1990s as cell phones went from analog to digital, enabled messaging and call and text encryption to keep communications secure.

In 1998, 3G made video calling and mobile Internet access possible. 4G, introduced in 2008, supports HD TV via mobile, video conferencing and gaming. Today most cell phones use 3G and 4G technology.

5G, which began deployment in 2019, can deliver enhanced broadband for cell phones, super fast and reliable communication, and machine-to-machine communication. It promises to be 100 times faster than 4G. But beyond speed and connectivity, 5G also has ultra low latency—latency is any delay in communications—and 1,000 times more capacity because it is expanding into new frequencies of the spectrum. This will eventually make wireless Internet possible everywhere, from smart cars to the Internet of Things (IoT), which can connect all kinds of devices and sensors through the Internet and allow them to communicate without human involvement.

How does 5G work?

The spectrum

To understand what 5G is, it’s important to first understand the spectrum. The electromagnetic spectrum is the range of all types of electromagnetic radiation. The radio spectrum is the part of the spectrum used for telecommunication, broadcast, aircraft communication and more, and ranges from 30 hertz (Hz) to 300 gigahertz (1 GHz is equal to 1 billion hertz). The overall spectrum also includes visible light, gamma rays, x-rays, microwaves, etc. Spectrum on the lower end, called low-band (600 million hertz (MHz) to 900 MHz) has longer waves and can travel farther. As waves range from mid-band (2.5GHz to 4.2GHz) to high-band—also known as millimeter wave (24GHz to 47GHz)—they get shorter and shorter, enabling more bandwidth (the amount of data that can be transmitted in a specific amount of time) but losing the ability to travel as far.

While low-band can penetrate walls well, its speed is limited to 100 megabytes per second (Mbps). Mid-band spectrum speed can reach 1 billion bytes or 1 gigabyte per second (Gbps); it has lower latency than low-band, but it cannot go through buildings as easily. High-band or millimeter wave (mmWave) has very low latency and is super fast, up to 10 Gbps. These high frequency mmWaves also offer increased transmission space so more devices can be connected at once. The drawback is that they are weaker and cannot easily penetrate solids. 5G operates on all three spectrum bands.

Government agencies in every country control the spectrum and designate who can use which frequencies. In the United States, the Federal Communications Commission (FCC) controls the spectrum and separates it into different chunks, which are then assigned or sold to companies and industries. In 2016, the FCC opened up large amounts of high-band spectrum for 5G.

Infrastructure and data transmission

Because mmWaves can travel only a short distance, small cell towers, about the size of a medium suitcase, will need to be placed 250 meters apart, such as on rooftops, telephone poles, trees, and street lights to ensure comprehensive coverage in cities.

Unlike tall 4G cell towers that transmit longer frequency waves over longer distances, the small cell base stations, containing the equipment that transmits data to and from devices, need a direct line of sight to the devices with which they communicate.

The base stations house a large number of antennae, which increases the capacity of the network. These antennae use “beamforming” to coordinate the numerous transmissions, prevent them from interfering with each other, and send focused data to the specific individual user. This enables the small cell to handle many different data streams at the same time. The small cells are connected to the 5G network and Internet usually via fiber optic cable or wireless microwave. They also need a power source. A typical small cell may require 200 to 1,000 watts of power.

To enable the network to respond to all types of demands, “network slicing” creates self-contained networks or slices that meet different needs and requirements. For example, one network slice could require only low -security and low bandwidth while another needs high security and high reliability.

Satellites can provide 5G coverage where it is difficult to build enough cell towers, as well as take over critical functions if a natural disaster or terrorist attack knocks out the communication infrastructure on land. Recently, SpaceX, Elon Musk’s company, launched 595 small satellites (with an ultimate goal of 30,000) that orbit in low Earth orbit (LEO), 500 to 2,000 kilometers above Earth. The FCC has approved other LEO satellite systems including Amazon’s Kuiper System of 3,236 satellites; and a number of systems have been approved by other countries as well. The constellations of LEO satellites will hand off transmission between the individual satellites to provide extensive coverage in the air, at sea and in remote areas. But larger satellites that already operate in orbits farther from Earth can also handle 5G transmission. The various satellite systems differ in their coverage, power requirements, latency and economic viability.

How can 5G help the environment?

The speed, capacity and connectivity of 5G will provide many opportunities to protect and preserve the environment. 5G technology with IoT will be able to increase energy efficiency, reduce greenhouse gas emissions and enable more use of renewable energy. It can help reduce air and water pollution, minimize water and food waste, and protect wildlife. It can also expand our understanding of and hence improve decision-making about weather, agriculture, pests, industry, waste reduction and much more.

According to the UN, 68 percent of the world’s population will live in cities by 2050. City governments and businesses are looking to 5G, artificial intelligence (AI) and IoT technology to create smart cities where sensors, cameras and smart phones will be linked; the connectivity and speed of these networks will enable cities to be better managed and more efficient and sustainable.

Here are just some of the ways, 5G can benefit the environment.

Reducing energy consumption and emissions

International standards have called for 5G to require much less energy to run than 4G, which means using less power while transmitting more data. For example, one kilowatt-hour (kWh) of electricity is needed to download 300 high-definition movies in 4G; with 5G, one kWh can download 5,000 ultra-high-definition movies.

5G linked with IoT will also cut energy use, because devices will be able to power up and shut down automatically when not needed. Sensors in appliances, transportation networks, buildings, factories, street lights, residences and more will monitor and analyze their energy needs and consumption in real time and automatically optimize energy use. For example, smart electricity meters installed in the Empire State Building have helped cut energy costs by 38 percent. GE’s Digital Power Plant for Steam in France, equipped with 10,000 sensors to improve plant efficiency, got the Guinness World Record for the world’s most efficient power plant.

Because saving energy also means cutting greenhouse gas emissions, GE’s Digital Power Plant software is expected to reduce carbon emissions by 3 percent and fuel use by 67,000 tons of coal per year. A study done by Ericcson, a leading information and communication technology provider, projects that IoT could cut carbon emissions 15 percent by 2030.

5G and the IoT will enable microgrids to be brought on line when the main grid fails or is unavailable. This will make it possible to better integrate intermittent renewable energy sources such as wind and solar into the grid. Ameresco, a Massachusetts-based company, replaced an old steam plant with a fully automated plant supported by 20,000 solar modules and its own microgrid at the U.S. Marine Corps Recruit Depot on Parris Island, S.C. The system reduced energy use by 75 percent.

By enabling more people to work or access entertainment remotely and avoid commuting and flying for business, 5G will save energy and reduce greenhouse gas emissions from vehicles and airplanes.

If driving is a necessity, 5G can save time, fuel and vehicle emissions by reducing traffic congestion and idling. With sensors and cameras, 5G uses real time data to keep traffic flowing, changing traffic lights to avoid delay. Carnegie Mellon’s Metro21: Smart Cities Institute’s smart traffic control system, which employs radar and cameras to reduce idling, has resulted in 20 percent fewer greenhouse gas emissions in Pittsburgh. 5G can also reduce the number of cars on the road by helping drivers find parking spaces and enabling ride sharing.

Reducing water and food waste

According to the EPA, U.S. households waste one trillion gallons each year due to leaks. Smart water sensors can detect leaks, as well as water pollution and contamination.

Sensors can also optimize agricultural water use. Arable, an innovative agricultural company, uses smart agricultural sensors that incorporate weather information and soil and crop conditions to better manage irrigation and make it more efficient. The systems also monitor plant stress, nutrients and pests to help plan harvests.

The UN has estimated that about one-third of the food produced globally is wasted, which also wastes the energy and water that went into it. Agricultural sensors can detect when a plant is wilting, so they can help ensure that crops are harvested at the right time. Other sensors can detect food freshness and spoilage, so that consumers know when food is safe to eat without depending on expiration dates. 5G could eventually be used to tag all food where it’s produced, track harvest dates or identify specific animals, and then trace the smart tags as food is transported to the factory. Other sensor systems could monitor conditions in the factory, assessing the food for quality and compliance with regulations. An automated and transparent system could make sure that the correct ingredients are delivered at the right time and packaged properly. This would help reduce food waste, maximize food safety, evaluate a food’s sustainability, and allow a supply chain to respond more quickly to supply and demand issues.

Protecting nature

To keep sewage from polluting the St. Joseph River in South Bend, Ind., smart sewer technology was installed in manholes. The technology reduced sewage overflows by 70 percent —over one billion gallons a year—and saved the city more than $500 million.

Toxic blue-green algae bloom when water temperatures are warmer than usual. Nokia used 5G drones with cameras and sensors over the Baltic Sea to detect blue-green algae growth in real time. While algae are normally monitored by observation from shore, the drones made it possible to detect algae blooms in more remote areas. Getting timely information enables experts to rapidly take actions to prevent such environmental hazards.

Australian start-up Myriota and the Australian Institute of Marine Science (AIMS) are using marine buoys with satellite-connected IoT sensors to track ocean currents, sea surface water temperatures, and the barometric pressure of the ocean in real time. This helps researchers better monitor changing conditions in the ocean and understand how the ocean behaves.

Rainforest Connection, a nonprofit fighting illegal deforestation, is working with 5G and AI to protect the rainforest in Costa Rica. AI recorders recognize the sounds of chainsaws and other machinery, so they can alert rangers about illegal logging in real time. They can also distinguish the sounds of animals under stress so that rangers can respond quickly to illegal poaching.

The International Union for Conservation of Nature uses 5G geolocation technology to track the location and movements of endangered animals. And at the Chengdu Research Base of Giant Panda Breeding in China, 5G is being used to monitor panda conditions and encourage breeding. Pandas only ovulate once a year and are fertile for only 24 to 36 hours so breeding them is challenging. The technology identifies panda mating calls and plays them back to the pandas to encourage them to mate with each other.

5G’s potentially negative impacts on the environment

Since 5G is a new technology, its long-term effects on the environment are unknown. However, there are already concerns that 5G could have negative effects on the environment because of its energy use, and the impacts of manufacturing new infrastructure and a multitude of new devices.

More energy consumption and emissions

Currently, information and communications technology is responsible for about 4 percent of global electricity consumption, and 1.4 percent of global carbon emissions.  But an Ericcson report projects that by the end of 2025, 5G will have 2.6 billion subscribers; total global mobile subscriptions are expected to reach 5.8 billion by then. By 2030, IoT devices around the world could number 125 billion. At that point, information technology is expected to be responsible for one-fifth of all global electricity consumption and by 2040, it could generate 14 percent of worldwide greenhouse gas emissions. If the entire system is not energy efficient, 5G will ultimately not be sustainable.

Data storage centers that handle cloud computing and websites, and store our information use enormous amounts of energy—as much as 80 percent of total network energy use. About half of this goes towards keeping transmission equipment in base stations cool. A Berkeley Lab report found that U.S. data centers consumed 70 billion kWh in 2014; this year they are projected to consume 73 billion kWh. Small cell base stations may devour three times as much power as 4G base stations.

Life cycle impacts

In 2019, the president of The Shift Project, a French think tank advocating the shift to a post-carbon economy, said, “…behind each byte we have mining and metal processing, oil extraction and petrochemicals, manufacturing and intermediate transports, public works (to bury the cables) and power generation with coal and gas. As a result, the carbon footprint of the global digital system is already four percent of the global greenhouse gas emissions, and its energy consumption rises by nine percent per year.”

The increase in greenhouse gas emissions will be due in part to the fact that consumers will need to buy new 5G mobile phones in order to take full advantage of 5G. A Swedish study calculated that a smart phone produced 45 kg of CO2 during its entire lifetime, with most of it coming from the production phase—the manufacture of integrated circuits, sourcing the raw material, production of the phone shell, then assembly and distribution. If accessories and the mobile network are included, the total life cycle impact is 68 kg CO2.

The manufacture of more IoT devices and cell phones, and small cells also means more mining and use of many nonrenewable metals that are difficult to recycle.

As consumers around the world move to 5G phones, many older phones and IoT devices will be discarded if there are no buy back or recycling plans for them. This will result in enormous amounts of e-waste , which is already a huge global problem.

The full deployment of 5G could have a disruptive impact on ecosystems. A Punjab University study found that sparrows exposed to cell tower radiation for five to 30 minutes produced disfigured eggs. In Spain, the nesting, breeding and roosting of birds were disturbed by microwave radiation from a cell tower. Wireless frequencies have also been found to interfere with the navigational systems and circadian rhythms of birds, affecting migration.

Another study found that bees exposed to low-band spectrum radiation for 10 minutes suffered colony collapse disorder. And some research has found that insects, including honeybees, absorb more radiation from the mid-band and 5G spectrum. This could lead to changes in insect behavior and functions over time.

With 5G expected to require the installation of 70.2 million small cell towers by 2025—one survey found that many operators expect to deploy between 100 and 350 small cells per square kilometer (indoors and outdoors)—it is unknown what effect ubiquitous mmWave radiation could have on birds, bees and other species.

Making 5G more sustainable

There are strategies that can and should be employed to lessen the environmental impacts of 5G and make it more sustainable.

Decarbonization

Steve Cohen, director of the Master of Public Administration Program in Environmental Science and Policy at Columbia University’s School of International and Public Affairs, stressed that since 5G will consume a great deal of electricity, decarbonizing our electrical system is critical.

This means replacing fossil fuels with renewable energy, improving grid flexibility and storage, and using carbon-capture strategies with any remaining fossil fuel power plants.

More efficient cooling

Some companies are implementing new technologies to reduce the amount of energy networks consume to cool their base stations. In Hangzhou, China, new base stations using intelligent voltage boosting and cooling, and solar modules can save 4,310 KWh of power per site each year, cutting 1,125 kilograms of CO2 emissions. NTT DOCOMO, a Japanese mobile phone company, has developed Green Base Stations with solar photo-voltaic panels and smart power control, reducing commercial power consumption by 40 percent.

Nokia deployed a liquid-cooled base station in Finland; using water to cool the station instead of air consumed 10 percent of the energy of traditional air cooling. With water cooling, it was also possible to use the waste heat from the base stations for water or space heating in the buildings next to the base stations. In addition, data centers cooled with liquid reduced carbon emissions by 90 percent.

Biodegradable sensors

Most of the sensors incorporated into phones, computers and other electronic devices are composed of precious metals that can be harmful to the environment or human health. Some scientists are working on developing biodegradable sensors that dissolve when they are no longer needed. Such sensors could be based on paper or polylactic acid, which are biodegradable, and are already used in medical applications. Researchers at École Polytechnique Fédérale de Lausanne have developed printed humidity and temperature sensors and transistors on biodegradable substances, which could eventually be applied to smart packaging.

Recycling toxic materials

“The biggest danger [about 5G] that I see is the toxics of electronic waste,” said Cohen, “Some of the rare earths and other substances inside of phones can be reused fairly easily and can be mined. The companies that sell them should be required to buy them back at the end—it’s called producer responsibility.” He expects there will be more mining of existing electronic devices by companies that give consumers a discount for trading in their old one, as Apple now does.

Network sharing

Some companies are sharing 5G network infrastructure to potentially cut 30 percent of their costs. McKinsey, the management consulting firm, found that costs to set up small cell base stations could be reduced by half if three players share the network. In China, two companies have agreed to build a 5G network together and share the network infrastructure. Vodafone and Telecom Italia are sharing a network, as are three mobile network operators in South Korea. Beyond cutting costs, network sharing can also reduce environmental impacts by avoiding overlapping dense networks of small cells and reducing the need for equipment and construction in cities.

When will 5G arrive?

The full potential of 5G in cities will be realized only when there is full indoor and outdoor 5G. This will require transmission equipment for IoT to be installed in buildings, on city streets, as well as along transportation routes so that traffic and autonomous vehicles can be managed.

However, because it doesn’t yet make economic sense to build completely new 5G infrastructure, 5G’s rollout will be “evolutionary.” 5G will initially piggyback on the existing 4G network. This entails allowing mobile operators to replace the older equipment in a frequency band with newer equipment. To accommodate 5G, 4G networks will be upgraded to their most advanced versions; some of these advanced 4G cell towers have the capability of being upgraded via software in the future. It is only when both the network infrastructure and the device being used support the same standard that it will be possible for consumers to access all the benefits of 5G; otherwise the service will default to the network that both connections support.

As of June 2020, 5G was available to some degree in 38 countries. In the United States, the three major cell phone carriers (T-Mobile/Sprint, Verizon, AT&T) have deployed some 5G in major cities, and this week, the White House and the Defense Department opened up a new chunk of the spectrum to help speed the 5G rollout. But the extent of 5G service still depends on the availability of more new devices—cell phones and smart sensors. These are expected to be launched late this year and into 2021. The prevailing thinking is that worldwide adoption of 5G is three years away.

Whether or not 5G will be a boon or a bane for the environment remains to be seen. The calculus is complex. “You can’t just look at the technology, use of energy, and use of toxics,” said Cohen. “It’s not a straightforward analysis. I think that, in general, people spending more and more of their time consuming information and entertainment has a lower environmental impact than many of the other things people do, like shopping or driving around. We have to look at this activity compared to what else you’d be doing with your time, and what other environmental impact you’d be having if you weren’t doing this. What would that something else be?”

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5g network is bad for the enviorment to much radiation

“I agree to help cultivate an open and respectful discussion. I understand rude and/or profane comments, and comments that spread misinformation, will be automatically deleted.”

I’m waiting for this policy to be applied.

It is not misinformation. Scientific Research on 5G, 4G Small Cells, Wireless Radiation and Health – Environmental Health Trust (ehtrust.org)

it is misinformation.

“There’s often confusion between ionizing and non-ionizing radiation because the term radiation is used for both,” said Kenneth Foster, a professor of bio engineering at Pennsylvania State University. “All light is radiation because it is simply energy moving through space. It’s ionizing radiation that is dangerous because it can break chemical bonds.”-livescience.com

Outra fonte Final RF Charts power density Rev Sep14.xlsx (bioinitiative.org)

nope it isn’t bad for anyone because the are non ionized waves(for the easier explanation there is no evidence/scientists don’t see any bad effect because they don’t cause harm.)

Very well written, informative and balanced article. Benefits listed would be better realised, if it’s negative impacts, which are equally important, are well managed. We need well informed, responsible and effective governments and policy making bodies to make that happen, and equally effective executive bodies to implement it, else we will end up doing more damage to ourselves than reap it’s benefits. So, the big question is how do we ensure, we get such governments and what are the do’s and don’ts for such governments? What policies should we have in place?

Good read, very interesting

Why is 5G towers creating a low pressure and making bad storms, get ready for the epic 5G hurricane season

I have lived in a Class I wetland, 2500 acres for 50 years this year. Since 5G was turned on (here) this winter we have had ZERO ducks in our wetland. Not a coot, hell diver, Merganser, wood duck, black duck or mallard. The only ducks that passed through were sea ducks in March and April. The last sea duck I saw was April 28.

Even though the Audubon society had debunked that 5G was harming wildlife (birds to be more specific), there are speculations the cell frequencies may affect how Migratory birds navigate, though it is not a harmful degree. This could be the reason that the ducks haven’t should up last winter. (Not a Hate comment, I am just trying to give a possible reason)

…so the goal of all this is to get us all doing nothing but “consuming information and entertainment”. Malevolently suspect.

Can 5G towers close to you affect my ground water ? I have a well 400ft deep. I have been wondering about this.

“With 5G expected to require the installation of 70.2 million small cell towers by 2025—one survey found that many operators expect to deploy between 100 and 350 small cells per square kilometer (indoors and outdoors)—it is unknown what effect ubiquitous mmWave radiation could have on birds, bees and other species.”

Seriously, the time to find out what effect these devices have on ourselves and our wildlife and fauna is BEFORE they are deployed. Not once we are economically, politically, academically, and socially committed to and addicted to them.

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Essay on 5G Technology | 5G Technology in India

This long essay on 5G Technology in English is suitable for students of classes 5, 6, 7, 8, 9 and 10, 11, 12 and also for competitive exam aspirants. Read and enjoy the complete information about the essay on 5G Technology .

All important information regarding the Essay on 5G Technology is discussed in the article. After reading this article, we got all the important regarding What is 5G Technology, How does 5G Works, Evaluation from First Generation to Fifth Generation, the Advantages and disadvantages of 5G Technology, and the Challenges of 5G Technology.

Essay on 5G Technology in English 800 Words

Introduction.

5G Technology Essay – 5G Technology is the next generation of mobile broadband that will eventually replace, or at least expand 4G LTE  connections. Long-term development (LTE) is a standard for wireless broadband communications for mobile devices and data terminals.

5G is a new revolutionary technology in the field of telecommunications.  This technology is set to play an unprecedented role in the field of communication in place of 4G in the future.  This technology started from the south is also being introduced in India, which will give great impetus to the important programs of India’s social, economic, defense, space, etc, and the development of the nation will be faster.

5G technology is the fifth generation of the Internet and is considered the fastest and most secure means of data transfer. Its speed will be more than about 1 Gbps, which is about ten times more than a normal wireless mobile phone. The 5G is much more powerful than its previous generations due to its high-speed data transfer and low latency.

How does 5G Work?

The transmission of the 5G network will not require any type of tower, but rather the transmission of signals through small cell stations in rooftops or electric poles.  These small cells are significantly more important because of the millimeter-wave spectrum.

Various state-of-the-art technologies under 5 G technologies, such as MIMO, TDD, etc. will be used.  Multiple Input Multiple Output (MIMO) technology will provide downloading capability with an intensity of around 952 Mbps.

Evaluation from First Generation to Fifth Generation

• 1G Technology was launched in the 1980s and worked on analog radio signals and supported only voice calls.
• 2G Technology was launched in the 1990s which uses digital radio signals and supported both voice and data transmission with a Bandwidth of 64 Kbps.
• 3G Technology was launched in the 2000s with a speed of 1 Mbps to 2 Mbps and it has the ability to transmit telephone signals including digitized voice, video calls ad conferencing.
• 4G Technology was launched in 2009 with a peak speed of 100 Mbps to 1 Gbps and it also enables 3D virtual reality.

Advantages of 5G Technology

Some of the important advantages of an essay on 5G technology are:-

• A committee on 5G technology was formed in India, which in its recommendation for an increase in the amount of spectrum available and a decrease in the value of spectrum in the initial allocation of 5G spectrum.
• 5G technology is expected to offer advanced mobile broadband that can meet high coverage requirements.
• If the 5G technology is successfully implemented in India, it will revolutionize the Indian telecom sector.
• This technology will accelerate the Digital India program of the Government of India, Make in India, and Ease of Doing Business. Apart from this, New India Mission, Smart City Project, Bharat Net Project, etc. can be made successful.
• The high data speed of the 5G Network might help cloud systems steam software updates, music, and navigation data.
• 5G will also facilitate the ecosystem for the Internet of Things.
• The 5G technology, called the fifth generation of the Internet, can be used to increase India’s GDP, digitize the employment generation economy, etc.
• 5G Technology will help in the country’s digital growth which will result in the rise of GDP and employment generation in the country.
• 5G technology will help to incorporate Artificial Intelligence into our daily lives.
• It is estimated that 5G technology will boost the digital economy in India, helping India achieve a $ 5 trillion economy by 2024.

Challenges of 5G Technology

Some of the challenges of the essay on 5G technology are:-

• According to information and communications technology experts, India lacks the appropriate infrastructure for 5G, and developing it is a challenge in itself.
• The proposed speed of 5G is brutal considering the inefficient technical support in most parts of the world.
• 5G connection is more expensive than the currently available network . 5G requires investors to invest more than $ 2000 billion annually, discouraging investors.
• Reliance Jio’s entry into the Indian telecom sector in 2016 has also led to a decline in revenue from other sector operators.
• The switch from 4G to 5G will be infrastructure intensive & the development of infrastructure for 5G is very expensive.

It is true that there are challenges related to infrastructure, investment, and health related to 5G technology in India right now, but the government should address these challenges as soon as possible and implement this technology in India. The introduction of 5G technologies in India, economic, socio-strategic, etc., will bring dynamism in all areas and the development of the country will be further strengthened.

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In the tech world and beyond, new 5G applications are being discovered every day. From driverless cars to smarter cities, farms, and even shopping experiences, the latest standard in wireless networks is poised to transform the way we interact with information, devices and each other. What better time to take a closer look at how humans are putting 5G to use to transform their world.

What is 5G?

5G (fifth-generation mobile technology  is the newest standard for cellular networks. Like its predecessors, 3G, 4G and 4G LTE, 5G technology uses radio waves for data transmission. However, due to significant improvements in latency, throughput and bandwidth, 5G is capable of faster download and upload speeds than previous networks.

Since its release in 2019, 5G broadband technology has been hailed as a breakthrough technology with significant implications for both consumers and businesses. Primarily, this is due to its ability to handle large volumes of data that is generated by complex devices that use its networks.

As mobile technology has expanded over the years, the number of data users generate every day has increased exponentially. Currently, other transformational technologies like  artificial intelligence (AI),  the  Internet of Things (IoT ) and  machine learning (ML)  require faster speeds to function than 3G and 4G networks offer. Enter 5G, with its lightning-fast data transfer capabilities that allow newer technologies to function in the way they were designed to.

Here are some of the biggest differences between 5G and previous wireless networks.

• Physical footprint : The transmitters that are used in 5G technology are smaller than in predecessors’ networks, allowing for discrete placement in out-of-the-way places. Furthermore, “cells”—geographical areas that all wireless networks require for connectivity—in 5G networks are smaller and require less power to run than in previous generations.
• Error rates : 5G’s adaptive Modulation and Coding Scheme (MCS), a schematic that wifi devices use to transmit data, is more powerful than ones in 3G and 4G networks. This makes 5G’s Block Error Rate (BER)—a metric of error frequency—much lower. 
• Bandwidth : By using a broader spectrum of radio frequencies than previous wireless networks, 5G networks can transmit on a wider range of bandwidths. This increases the number of devices that they can support at any given time.
• Lower latency : 5G’s low  latency , a measurement of the time it takes data to travel from one location to another, is a significant upgrade over previous generations. This means that routine activities like downloading a file or working in the cloud is going to be faster with a 5G connection than a connection on a different network.

Like all wireless networks, 5G networks are separated into geographical areas that are known as cells. Within each cell, wireless devices—such as smartphones, PCs, and IoT devices—connect to the internet via radio waves that are transmitted between an antenna and a base station. The technology that underpins 5G is essentially the same as in 3G and 4G networks. But due to its lower latency, 5G networks are capable of delivering faster download speeds—in some cases as high as 10 gigabits per second (Gbps).

As more and more devices are built for 5G speeds, demand for 5G connectivity is growing. Today, many popular Internet Service Providers (ISPs), such as Verizon, Google and AT&T, offer 5G networks to homes and businesses. According to Statista,  more than 200 million homes  and businesses have already purchased it with that number expected to at least double by 2028 (link resides outside ibm.com).

Let’s take a look at three areas of technological improvement that have made 5G so unique.

New telecom specifications

The 5G NR (New Radio) standard for cellular networks defines a new radio access technology (RAT) specification for all 5G mobile networks. The 5G rollout began in 2018 with a global initiative known as the 3rd Generation Partnership Project (3FPP). The initiative defined a new set of standards to steer the design of devices and applications for use on 5G networks.

The initiative was a success, and 5G networks grew swiftly in the ensuing years. Today, 45% of networks worldwide are 5G compatible, with that number forecasted to rise to 85% by the end of the decade according to  a recent report by Ericsson  (link resides outside ibm.com).

Independent virtual networks (network slicing)

On 5G networks, network operators can offer multiple independent virtual networks (in addition to public ones) on the same infrastructure. Unlike previous wireless networks, this new capability allows users to do more things remotely with greater security than ever before. For example, on a 5G network, enterprises can create use cases or business models and assign them their own independent virtual network. This dramatically improves the user experience for their employees by adding greater customizability and security.

Private networks

In addition to network slicing, creating a 5G private network can also enhance personalization and security features over those available on previous generations of wireless networks. Global businesses seeking more control and mobility for their employees increasingly turn to private 5G network architectures rather than public networks they’ve used in the past.

Now that we better understand how 5G technology works, let’s take a closer look at some of the exciting applications it’s enabling.

Autonomous vehicles

From taxi cabs to drones and beyond, 5G technology underpins most of the next-generation capabilities in autonomous vehicles. Until the 5G cellular standard came along, fully autonomous vehicles were a bit of a pipe dream due to the data transmission limitations of 3G and 4G technology. Now, 5G’s lightning-fast connection speeds have made transport systems for cars, trains and more, faster than previous generations, transforming the way systems and devices connect, communicate and collaborate.

Smart factories

5G, along with AI and ML, is poised to help factories become not only smarter but more automated, efficient, and resilient. Today, many mundane but necessary tasks that are associated with equipment repair and optimization are being turned over to machines thanks to 5G connectivity paired with AI and ML capabilities. This is one area where 5G is expected to be highly disruptive, impacting everything from fuel economy to the design of equipment lifecycles and how goods arrive at our homes.

For example, on a busy factory floor, drones and cameras that are connected to smart devices that use the IoT can help locate and transport something more efficiently than in the past and prevent theft. Not only is this better for the environment and consumers, but it also frees up employees to dedicate their time and energy to tasks that are more suited to their skill sets.

Smart cities

The idea of a hyper-connected urban environment that uses 5G network speeds to spur innovation in areas like law enforcement, waste disposal and disaster mitigation is fast becoming a reality. Some cities already use 5G-enabled sensors to track traffic patterns in real time and adjust signals, helping guide the flow of traffic, minimize congestion, and improve air quality.

In another example, 5G power grids monitor supply and demand across heavily populated areas and deploy AI and ML applications to “learn” what times energy is in high or low demand. This process has been shown to significantly impact energy conservation and waste, potentially reducing carbon emissions and helping cities reach sustainability goals.

Smart healthcare

Hospitals, doctors, and the healthcare industry as a whole already benefit from the speed and reliability of 5G networks every day. One example is the area of remote surgery that uses robotics and a high-definition live stream that is connected to the internet via a 5G network. Another is the field of mobile health, where 5G gives medical workers in the field quick access to patient data and medical history. This enables them to make smarter decisions, faster, and potentially save lives.

Lastly, as we saw during the pandemic, contact tracing and the mapping of outbreaks are critical to keeping populations safe. 5G’s ability to deliver of volumes of data swiftly and securely allows experts to make more informed decisions that have ramifications for everyone.

5G paired with new technological capabilities won’t just result in the automation of employee tasks, it will dramatically improve them and the overall  employee experience . Take virtual reality (VR) and augmented reality (AR), for example. VR (digital environments that shut out the real world) and AR (digital content that augments the real world) are already used by stockroom employees, transportation drivers and many others. These employees rely on wearables that are connected to a 5G network capable of high-speed data transfer rates that improve several key capabilities, including the following:

• Live views : 5G connectivity provides live, real-time views of equipment, events, and even people. One way in which this feature is being used in professional sports is to allow broadcasters to remotely call a sporting event from outside the stadium where the event is taking place.
• Digital overlays : IoT applications in a warehouse or industrial setting allow workers that are equipped with smart glasses (or even just a smartphone) to obtain real-time insights from an application. This includes repair instructions or the name and location of a spare part.
• Drone inspections : Right now, one of the leading causes of employee injury is inspection of equipment or project sites in remote and potentially dangerous areas. Drones, which are connected via 5G networks, can safely monitor equipment and project sites and even take readings from hard-to-reach gauges.

Edge computing , a computing framework that allows computations to be done closer to data sources, is fast becoming the standard for enterprises. According to  this Gartner white paper  (link resides outside ibm.com), by 2025, 75% of enterprise data will be processed at the edge (compared to only 10% today). This shift saves businesses time and money and enables better control over large volumes of data. It would be impossible without the new speed standards that are generated by 5G technology. 

Ultra-reliable edge computing and 5G enable the enterprise to achieve faster transmission speeds, increased control and greater security over massive volumes of data. Together, these twin technologies will help reduce latency while increasing speed, reliability and bandwidth, resulting in faster, more comprehensive data analysis and insights for businesses everywhere.

5G solutions with IBM Cloud Satellite  

5G presents significant opportunities for the enterprise, but first, you need a platform that can handle its speed. IBM Cloud Satellite® lets you deploy and run apps consistently across on-premises, edge computing and public cloud environments on a 5G network. And it’s all enabled by secure and auditable communications within the IBM Cloud®.

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5G mobile networks and health—a state-of-the-science review of the research into low-level RF fields above 6 GHz

• Ken Karipidis   ORCID: orcid.org/0000-0001-7538-7447 1 ,
• Rohan Mate 1 ,
• David Urban 1 ,
• Rick Tinker 1 &
• Andrew Wood 2  

Journal of Exposure Science & Environmental Epidemiology volume  31 ,  pages 585–605 ( 2021 ) Cite this article

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The increased use of radiofrequency (RF) fields above 6 GHz, particularly for the 5 G mobile phone network, has given rise to public concern about any possible adverse effects to human health. Public exposure to RF fields from 5 G and other sources is below the human exposure limits specified by the International Commission on Non-Ionizing Radiation Protection (ICNIRP). This state-of-the science review examined the research into the biological and health effects of RF fields above 6 GHz at exposure levels below the ICNIRP occupational limits. The review included 107 experimental studies that investigated various bioeffects including genotoxicity, cell proliferation, gene expression, cell signalling, membrane function and other effects. Reported bioeffects were generally not independently replicated and the majority of the studies employed low quality methods of exposure assessment and control. Effects due to heating from high RF energy deposition cannot be excluded from many of the results. The review also included 31 epidemiological studies that investigated exposure to radar, which uses RF fields above 6 GHz similar to 5 G. The epidemiological studies showed little evidence of health effects including cancer at different sites, effects on reproduction and other diseases. This review showed no confirmed evidence that low-level RF fields above 6 GHz such as those used by the 5 G network are hazardous to human health. Future experimental studies should improve the experimental design with particular attention to dosimetry and temperature control. Future epidemiological studies should continue to monitor long-term health effects in the population related to wireless telecommunications.

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Introduction.

There are continually emerging technologies that use radiofrequency (RF) electromagnetic fields particularly in telecommunications. Most telecommunication sources currently operate at frequencies below 6 GHz, including radio and TV broadcasting and wireless sources such as local area networks and mobile telephony. With the increasing demand for higher data rates, better quality of service and lower latency to users, future wireless telecommunication sources are planned to operate at frequencies above 6 GHz and into the ‘millimetre wave’ range (30–300 GHz) [ 1 ]. Frequencies above 6 GHz have been in use for many years in various applications such as radar, microwave links, airport security screening and in medicine for therapeutic applications. However, the planned use of millimetre waves by future wireless telecommunications, particularly the 5th generation (5 G) of mobile networks, has given rise to public concern about any possible adverse effects to human health.

The interaction mechanisms of RF fields with the human body have been extensively described and tissue heating is the main effect for RF fields above 100 kHz (e.g. HPA; SCENHIR) [ 2 , 3 ]. RF fields become less penetrating into body tissue with increasing frequency and for frequencies above 6 GHz the depth of penetration is relatively short with surface heating being the predominant effect [ 4 ].

International exposure guidelines for RF fields have been developed on the basis of current scientific knowledge to ensure that RF exposure is not harmful to human health [ 5 , 6 ]. The guidelines developed by the International Commission on Non-Ionizing Radiation Protection (ICNIRP) in particular form the basis for regulations in the majority of countries worldwide [ 7 ]. In the frequency range above 6 GHz and up to 300 GHz the ICNIRP guidelines prevent excessive heating at the surface of the skin and in the eye.

Although not as extensively studied as RF fields at lower frequencies, a number of studies have investigated the effects of RF fields at frequencies above 6 GHz. Previous reviews have reported studies investigating frequencies above 6 GHz that show effects although many of the reported effects occurred at levels greater than the ICNIRP guidelines [ 1 , 8 ]. Given the public concern over the planned roll-out of 5 G using millimetre waves, it is important to determine whether there are any related adverse health consequences at levels encountered in the environment. The aim of this paper is to present a state-of-the-science review of the bioeffects research into RF fields above 6 GHz at low levels of exposure (exposure below the occupational limits of the ICNIRP guidelines). A meta-analysis of in vitro and in vivo studies, providing quantitative effect estimates for each study, is presented separately in a companion paper [ 9 ].

The state-of-the-science review included a comprehensive search of all available literature and examined the extent, range and nature of evidence into the bioeffects of RF fields above 6 GHz, at levels below the ICNIRP occupational limits. The review consisted of biomedical studies on low-level RF electromagnetic fields from 6 GHz to 300 GHz published at any starting date up to December 2019. Studies were initially found by searching the databases PubMed, EMF-Portal, Google Scholar, Embase and Web of Science using the search terms “millimeter wave”, “millimetre wave”, “gigahertz”, “GHz” and “radar”. We further searched major reviews published by health authorities on RF and health [ 2 , 3 , 10 , 11 ]. Finally, we searched the reference list of all the studies included. Studies were only included if the full paper was available in English.

Although over 300 studies were considered, this review was limited to experimental studies (in vitro, in vivo, human) where the stated RF exposure level was at or below the occupational whole-body limits specified by the ICNIRP (2020) guidelines: power density (PD) reference level of 50 W/m 2 or specific absorption rate (SAR) basic restriction of 0.4 W/kg. Since the PD occupational limits for local exposure are more relevant to in vitro studies, and since these limits are higher, we have included those studies with PD up to 100–200 W/m 2 , depending on frequency. The review included studies below the ICNIRP general public limits that are lower than the occupational limits.

The review also included epidemiological studies (cohort, case-control, cross-sectional) investigating exposure to radar but excluded studies where the stated radar frequencies were below 6 GHz. Epidemiological studies on radar were included as they represent occupational exposure below the ICNIRP guidelines. Case reports or case series were excluded. Studies investigating therapeutical outcomes were also excluded unless they reported specific bio-effects.

The state-of-the-science review appraised the quality of the included studies, but unlike a systematic review it did not exclude any studies based on quality. The review also identified gaps in knowledge for future investigation and research. The reporting of results in this paper is narrative with tabular accompaniment showing study characteristics. In this paper, the acronym “MMWs” (or millimetre waves) is used to denote RF fields above 6 GHz.

The review included 107 experimental studies (91 in vitro, 15 in vivo, and 1 human) that investigated various bioeffects, including genotoxicity, cell proliferation, gene expression, cell signalling, membrane function and other effects. The exposure characteristics and biological system investigated in experimental studies for the various bioeffects are shown in Tables  1 – 6 . The results of the meta-analysis of the in vitro and in vivo studies are presented separately in Wood et al. [ 9 ].

Genotoxicity

Studies have examined the effects of exposing whole human or mouse blood samples or lymphocytes and leucocytes to low-level MMWs to determine possible genotoxicity. Some of the genotoxicity studies have looked at the possible effects of MMWs on chromosome aberrations [ 12 , 13 , 14 ]. At exposure levels below the ICNIRP limits, the results have been inconsistent, with either a statistically significant increase [ 14 ] or no significant increase [ 12 , 13 ] in chromosome aberrations.

MMWs do not penetrate past the skin therefore epithelial and skin cells have been a common model of examination for possible genotoxic effects. DNA damage in a number of epithelial and skin cell types and at varied exposure parameters both below and above the ICNIRP limits have been examined using comet assays [ 15 , 16 , 17 , 18 , 19 ]. Despite the varied exposure models and methods used, no statistically significant evidence of DNA damage was identified in these studies. Evidence of genotoxic damage was further assessed in skin cells by the occurrence of micro-nucleation. De Amicis et al. [ 18 ] and Franchini et al. [ 19 ] reported a statistically significant increase in micro-nucleation, however, Hintzsche et al. [ 15 ] and Koyama et al. [ 16 , 17 ] did not find an effect. Two of the studies also examined telomere length and found no statistically significant difference between exposed and unexposed cells [ 15 , 19 ]. Last, a Ukrainian research group examined different skin cell types in three studies and reported an increase in chromosome condensation in the nucleus [ 20 , 21 , 22 ]; these results have not been independently verified. Overall, there was no confirmed evidence of MMWs causing genotoxic damage in epithelial and skin cells.

Three studies from an Indian research group have examined indicators of DNA damage and reactive oxygen species (ROS) production in rats exposed in vivo to MMWs. The studies reported DNA strand breaks based on evidence from comet assays [ 23 , 24 ] and changes in enzymes that control the build-up of ROS [ 24 ]. Kumar et al. also reported an increase in ROS production [ 25 ]. All the studies from this research group had low animal numbers (six animals exposed) and their results have not been independently replicated. An in vitro study that investigated ROS production in yeast cultures reported an increase in free radicals exposed to high-level but not low-level MMWs [ 26 ].

Other studies have looked at the effect of low-level MMWs on DNA in a range of different ways. Two studies reported that MMWs induce colicin synthesis and prophage induction in bacterial cells, both of which are suggested as indicative of DNA damage [ 27 , 28 ]. Another study suggested that DNA exposed to MMWs undergoes polymerase chain reaction synthesis differently than unexposed DNA [ 29 ], although no statistical analysis was presented. Hintzsche et al. reported statistically significant occurrence of spindle disturbance in hybrid cells exposed to MMWs [ 30 ]. Zeni et al. found no evidence of DNA damage or alteration of cell cycle kinetics in blood cells exposed to MMWs [ 31 ]. Last, two studies from a Russian research group examined the protective effects of MMWs where mouse blood leukocytes were pre-exposed to low-level MMWs and then to X-rays [ 32 , 33 ]. The studies reported that there was statistically significant less DNA damage in the leucocytes that were pre-exposed to MMWs than those exposed to X-rays alone. Overall, these studies had no independent replication.

Cell proliferation

A number of studies have examined the effects of low-level MMWs on cell proliferation and they have used a variety of cellular models and methods of investigation. Studies have exposed bacterial cells to low-level MMWs alone or in conjunction with other agents. Two early studies reported changes in the growth rate of E. coli cultures exposed to low-level MMWs; however, both of these studies were preliminary in nature without appropriate dosimetry or statistical analysis [ 34 , 35 ]. Two studies exposed E. coli cultures and one study exposed yeast cell cultures to MMWs alone, and before and after UVC exposure [ 36 , 37 , 38 ]. All three studies reported that MMWs alone had no significant effect on bacterial cell proliferation or survival. Rojavin et al., however, did report that when E. coli bacteria were exposed to MMWs after UVC sterilisation treatment, there was an increase in their survival rate [ 36 ]. The authors suggested this could be due to the MMW activation of bacterial DNA repair mechanisms. Other studies by an Armenian research group reported a reduction in E. coli cell growth when exposed to MMWs [ 39 , 40 , 41 , 42 , 43 , 44 , 45 ]. These studies reported that when E.coli cultures were exposed to MMWs in the presence of antibiotics, there was a greater reduction in the bacterial growth rate and an increase in the time between bacterial cell division compared with antibiotics exposure alone. Two of these studies investigated if these effects could be due to a reduction in the activity of the E. coli ATPase when exposed to MMWs. The studies reported exposure to MMWs in combination with particular antibiotics changed the concentration of H + and K + ions in the E.coli cells, which the authors linked to changes in ATPase activity [ 43 , 44 ]. Overall, the results from studies on cell proliferation of bacterial cells have been inconsistent with different research groups reporting conflicting results.

Studies have also examined how exposure to low-level MMWs could affect cell proliferation in yeast. Two early studies by a German research group reported changes in yeast cell growth [ 46 , 47 ]. However, another two independent studies did not report any changes in the growth rate of exposed yeast [ 48 , 49 ]. Furia et al. [ 48 ] noted that the Grundler and Keilmann studies [ 46 , 47 ] had a number of methodical issues, which may have skewed their results, such as poor exposure control and analysis of results. Another study exposed yeast to MMWs before and after UVC exposure and reported that MMWs did not change the rates of cell survival [ 37 ].

Studies have also examined the possible effect of low-level MMWs on tumour cells with some studies reporting a possible anti-proliferative effect. Chidichimo et al. reported a reduction in the growth of a variety of tumour cells exposed to MMWs; however, the results of the study did not support this conclusion [ 50 ]. An Italian research group published a number of studies investigating proliferation effects on human melanoma cell lines with conflicting results. Two of the studies reported reduced growth rate [ 51 , 52 ] and a third study showed no change in proliferation or in the cell cycle [ 53 ]. Beneduci et al. also reported changes in the morphology of MMW exposed cells; however, the authors did not present quantitative data for these reported changes [ 51 , 52 ]. In another study by the same Italian group, Beneduci et al. reported that exposure to low-level MMWs had a greater than 40% reduction in the number of viable erythromyeloid leukaemia cells compared with controls; however, there was no significant change in the number of dead cells [ 54 ]. More recently, Yaekashiwa et al. reported no statistically significant effect in proliferation or cellular activity in glioblastoma cells exposed to low-level MMWs [ 55 ].

Other studies did not report statistically significant effects on proliferation in chicken embryo cell cultures, rat nerve cells or human skin fibroblasts exposed to low-level MMWs [ 55 , 56 , 57 ].

Gene expression

Some studies have investigated whether low-level MMWs can influence gene expression. Le Queument et al. examined a multitude of genes using microarray analyses and reported transient expression changes in five of them. However, the authors concluded that these results were extremely minor, especially when compared with studies using microarrays to study known pollutants [ 58 ]. Studies by a French research group have examined the effect of MMWs on stress sensitive genes, stress sensitive gene promotors and chaperone proteins in human glial cell lines. In two studies, glial cells were exposed to low-level MMWs and there was no observed modification in the expression of stress sensitive gene promotors when compared with sham exposed cells [ 59 , 60 , 61 ]. Further, glial cells were examined for the expression of the chaperone protein clusterin (CLU) and heat shock protein HSP70. These proteins are activated in times of cellular stress to maintain protein functions and help with the repair process [ 60 ]. There was no observed modification in gene expression of the chaperone proteins. Other studies have examined the endoplasmic reticulum of glial cells exposed to MMWs [ 62 , 63 ]. The endoplasmic reticulum is the site of synthesis and folding of secreted proteins and has been shown to be sensitive to environmental insults [ 62 ]. The authors reported that there was no elevation in mRNA expression levels of endoplasmic reticulum specific chaperone proteins. Studies of stress sensitive genes in glial cells have consistently shown no modification due to low-level MMW exposure [ 59 , 60 , 61 , 62 , 63 ].

Belyaev and co-authors have studied a possible resonance effect of low-level MMWs primarily on Escherichia Coli (E. coli) cells and cultures. The Belyaev research group reported that the resonance effect of MMWs can change the conformation state of chromosomal DNA complexes [ 64 , 65 , 66 , 67 , 68 , 69 , 70 , 71 , 72 , 73 , 74 ]; however, most of these experiments were not temperature controlled. This resonance effect was not supported by earlier experiments on a number of different cell types conducted by Gandhi et al. and Bush et al. [ 75 , 76 ].

The results of Belyaev and co-workers have primarily been based on evidence from the anomalous viscosity time dependence (AVTD) method [ 77 ]. The research group argued that changes in the AVTD curve can indicate changes to the DNA conformation state and DNA-protein bonds. Belyaev and co-workers have reported in a number of studies that differences in the AVTD curve were dependent on several parameter including MMW characteristics (frequency, exposure level, and polarisation), cellular concentration and cell growth rate [ 69 , 71 , 72 , 73 , 74 ]. In some of the Belyaev studies E. coli were pre-exposed to X-rays, which was reported to change the AVTD curve; however, if the cells were then exposed to MMWs there was no longer a change in the AVTD curve [ 64 , 65 , 66 , 67 ]. The authors suggested that exposure to MMWs increased the rate of recovery in bacterial cells previously exposed to ionising radiation. The Belyaev group also used rat thymocytes in another study and they concluded that the results closely paralleled those found in E. coli cells [ 67 ]. The studies on the DNA conformation state change relied heavily on the AVTD method that has only been used by the Balyaev group and has not been independently validated [ 78 ].

Cell signalling and electrical activity

Studies examining effects of low-level MMWs on cell signalling have mainly involved MMW exposure to nervous system tissue of various animals. An in vivo study on rats recorded extracellular background electrical spike activity from neurons in the supraoptic nucleus of the hypothalamus after MMW exposure [ 79 ]. The study reported that there were changes in inter-spike interval and spike activity in the cells of exposed animals when compared with controls. There was also a mixture of significant shifts in neuron population proportions and spike frequency. The effect on the regularity of neuron spike activity was greater at higher frequencies. An in vitro study on rat cortical tissue slices reported that neuron firing rates decreased in half of the samples exposed to low-level MMWs [ 80 ]. The width of the signals was also decreased but all effects were short lived. The observed changes were not consistent between the two studies, but this could be a consequence of different brain regions being studied.

In vitro experiments by a Japanese research group conducted on crayfish exposed the dissected optical components and brain to MMWs [ 81 , 82 ]. Munemori and Ikeda reported that there was no significant change in the inter-spike intervals or amplitude of spontaneous discharges [ 81 ]. However, there was a change in the distribution of inter-spike intervals where the initial standard deviation decreased and then restored in a short time to a rhythm comparable to the control. A follow-up study on the same tissues and a wide range of exposure levels (many above the ICNIRP limits) reported similar results with the distribution of spike intervals decreasing with increasing exposure level [ 82 ]. These results on action potentials in crayfish tissue have not been independently investigated.

Mixed results were reported in experiments conducted by a US research group on sciatic frog nerve preparations. These studies applied electrical stimulation to the nerve and examined the effect of MMWs on the compound action potentials (CAPs) conductivity through the neurological tissue fibre. Pakhomov et al. found a reduction in CAP latency accompanied by an amplitude increase for MMWs above the ICNIRP limits but not for low-level MMWs [ 83 ]. However, in two follow-up studies, Pakhomov et al. reported that the attenuation in amplitude of test CAPs caused by high-rate stimulus was significantly reduced to the same magnitude at various MMW exposure levels [ 84 , 85 ]. In all of these studies, the observed effect on the CAPs was temporal and reversible, but there were implications of a frequency specific resonance interaction with the nervous tissue. These results on action potentials in frog sciatic nerves have not been investigated by others.

Other common experimental systems involved low-level MMW exposure to isolated ganglia of leeches. Pikov and Siegel reported that there was a decrease in the firing rate in one of the tested neurons and, through the measurement of input resistance in an inserted electrode, there was a transient dose-dependent change in membrane permeability [ 86 ]. However, Romanenko et al. found that low-level MMWs did not cause suppression of neuron firing rate [ 87 ]. Further experiments by Romanenko et al. reported that MMWs at the ICNIRP public exposure limit and above reported similar action potential firing rate suppression [ 88 ]. Significant differences were reported between MMW effects and effects due to an equivalent rise in temperature caused by heating the bathing solution by conventional means.

Membrane effects

Studies examining membrane interactions with low-level MMWs have all been conducted at frequencies above 40 GHz in in vitro experiments. A number of studies investigated membrane phase transitions involving exposure to a range of phospholipid vesicles prepared to mimic biological cell membranes. One group of studies by an Italian research group reported effects on membrane hydration dynamics and phase transition [ 89 , 90 , 91 ]. Observations included transition delays from the gel to liquid phase or vice versa when compared with sham exposures maintained at the same temperature; the effect was reversed after exposure. These reported changes remain unconfirmed by independent groups.

A number of studies investigated membrane permeability. One study focussed on Ca 2+ activated K + channels on the membrane surface of cultured kidney cells of African Green Marmosets [ 92 ]. The study reported modifications to the Hill coefficient and apparent affinity of the Ca 2+ by the K + channels. Another study reported that the effectiveness of a chemical to supress membrane permeability in the gap junction was transiently reduced when the cells were exposed to MMWs [ 93 , 94 ]. Two studies by one research group reported increases in the movement of molecules into skin cells during MMW exposure and suggested this indicates increased cell membrane permeability [ 21 , 91 ]. Permeability changes based on membrane pressure differences were also investigated in relation to phospholipid organisation [ 95 ]. Although there was no evidence of effects on phospholipid organisation on exposed model membranes, the authors reported a measurable difference in membrane pressure at low exposure levels. Another study reported neuron shrinkage and dehydration of brain tissues [ 96 ]. The study reported this was due to influences of low-level MMWs on the cellular bathing medium and intracellular water. Further, the authors suggested this influence of MMWs may have led to formation of unknown messengers, which are able to modulate brain cell hydration. A study using an artificial axon system consisting of a network of cells containing aqueous phospholipid vesicles reported permeability changes with exposure to MMWs by measuring K + efflux [ 97 ]. In this case, the authors emphasised limitations in applying this model to processes within a living organism. The varied effects of low-level MMWs on membrane permeability lack replication.

Other studies have examined the shape or size of vesicles to determine possible effects on membrane permeability. Ramundo-Orlando et al., reported effects on the shape of giant unilamellar vesicles (GUVs), specifically elongation, attributed to permeability changes [ 98 ]. However, another study reported that only smaller diameter vesicles demonstrated a statistically significant change when exposed to MMWs [ 99 ]. A study by Cosentino et al. examined the effect of MMWs on the size distributions of both large unilamellar vesicles (LUVs) and GUVs in in vitro preparations [ 100 ]. It was reported that size distribution was only affected when the vesicles were under osmotic stress, resulting in a statistically significant reduction in their size. In this case, the effect was attributed to dehydration as a result of membrane permeability changes. There is, generally, lack of replication on physical changes to phospholipid vesicles due to low-level MMWs.

Studies on E. coli and E. hirae cultures have reported resonance effects on membrane proteins and phospholipid constituents or within the media suspension [ 39 , 40 , 41 , 42 ]. These studies observed cell proliferation effects such as changes to cell growth rate, viability and lag phase duration. These effects were reported to be more pronounced at specific MMW frequencies. The authors suggested this could be due to a resonance effect on the cell membrane or the suspension medium. Torgomyan et al. and Hovnanyan et al. reported similar changes to proliferation that they attributed to changes in membrane permeability from MMW exposure [ 43 , 45 ]. These experiments were all conducted by an Armenian research group and have not been replicated by others.

Other effects

A number of studies have reported on the experimental results of other effects. Reproductive effects were examined in three studies on mice, rats and human spermatozoa. An in vivo study on mice exposed to low-level MMWs reported that spermatogonial cells had significantly more metaphase translocation disturbances than controls and an increased number of cells with unpaired chromosomes [ 101 ]. Another in vivo study on rats reported increased morphological abnormalities to spermatozoa following exposure, however, there was no statistical analysis presented [ 102 ]. Conversely, an in vitro study on human spermatozoa reported that there was an increase in motility after a short time of exposure to MMWs with no changes in membrane integrity and no generation of apoptosis [ 103 ]. All three of these studies looked at different effects on spermatozoa making it difficult to make an overall conclusion. A further two studies exposed rats to MMWs and examined their sperm for indicators of ROS production. One study reported both increases and decreases in enzymes that control the build-up of ROS [ 104 ]. The other study reported a decrease in the activity of histone kinase and an increase in ROS [ 105 ]. Both studies had low animal numbers (six animals exposed) and these results have not been independently replicated.

Immune function was also examined in a limited number of studies focussing on the effects of low-level MMWs on antigens and antibody systems. Three studies by a Russian research group that exposed neutrophils to MMWs reported frequency dependant changes in ROS production [ 106 , 107 , 108 ]. Another study reported a statistically significant decrease in antigen binding to antibodies when exposed to MMWs [ 109 ]; the study also reported that exposure decreased the stability of previously formed antigen–antibody complexes.

The effect on fatty acid composition in mice exposed to MMWs has been examined by a Russian research group using a number of experimental methods [ 110 , 111 , 112 ]. One study that exposed mice afflicted with an inflammatory condition to low-level MMWs reported no change in the fatty acid concentrations in the blood plasma. However, there was a significant increase in the omega-3 and omega-6 polyunsaturated fatty acid content of the thymus [ 110 ]. Another study exposed tumour-bearing mice and reported that monounsaturated fatty acids decreased and polyunsaturated fatty acids increased in both the thymus and tumour tissue. These changes resulted in fatty acid composition of the thymus tissue more closely resembling that of the healthy control animals [ 111 ]. The authors also examined the effect of exposure to X-rays of healthy mice, which was reported to reduce the total weight of the thymus. However, when the thymus was exposed to MMWs before or after exposure to X-rays, the fatty acid content was restored and was no longer significantly different from controls [ 112 ]. Overall, the authors reported a potential protective effect of MMWs on the recovery of fatty acids, however, all the results came from the same research group with a lack of replication from others.

Physiological effects were examined by a study conducted on mice exposed to WWMs to assess the safety of police radar [ 113 ]. The authors reported no statistically significant changes in the physiological parameters tested, which included body mass and temperature, peripheral blood and the mass and cellular composition, and number of cells in several important organs. Another study exposing human volunteers to low-level MMWs specifically examined cardiovascular function of exposed and sham exposed groups by electrocardiogram (ECG) and atrioventricular conduction velocity derivation [ 114 ]. This study reported that there were no significant differences in the physiological indicators assessed in test subjects.

Other individual studies have looked at various other effects. An early study reported differences in the attenuation of MMWs at specific frequencies in healthy and tumour cells [ 115 ]. Another early study reported no effect in the morphology of BHK-21/C13 cell cultures when exposed to low-level MMWs; the study did report morphological changes at higher levels, which were related to heating [ 116 ]. One study examined whether low-level MMWs induced cancer promotion in leukaemia and Lewis tumour cell grafted mice. The study reported no statistically significant growth promotion in either of the grafted cancer cell types [ 117 ]. Another study looked at the activity of gamma-glutamyl transpeptidase enzyme in rats after treatment with hydrocortisone and exposure to MMWs [ 118 ]. The study reported no effects at exposures below the ICNIRP limit, however, at levels above authors reported a range of effects. Another study exposed saline liquid solutions to continuous low and high level MMWs and reported temperature oscillations within the liquid medium but lacked a statistical analysis [ 119 ]. Another study reported that low-level MMWs decrease the mobility of the protozoa S. ambiguum offspring [ 120 ]. None of the reported effects in all of these other studies have been investigated elsewhere.

Epidemiological studies

There are no epidemiological studies that have directly investigated 5 G and potential health effects. There are however epidemiological studies that have looked at occupational exposure to radar, which could potentially include the frequency range from 6 to 300 GHz. Epidemiological studies on radar were included as they represent occupational exposure below the ICNIRP guidelines. The review included 31 epidemiological studies (8 cohort, 13 case-control, 9 cross-sectional and 1 meta-analysis) that investigated exposure to radar and various health outcomes including cancer at different sites, effects on reproduction and other diseases. The risk estimates as well as limitations of the epidemiological studies are shown in Table  7 .

Three large cohort studies investigated mortality in military personnel with potential exposure to MMWs from radar. Studies reporting on over 40-year follow-up of US navy veterans of the Korean War found that radar exposure had little effect on all-cause or cancer mortality with the second study reporting risk estimates below unity [ 121 , 122 ]. Similarly, in a 40-year follow-up of Belgian military radar operators, there was no statistically significant increase in all-cause mortality [ 123 , 124 ]; the study did, however, find a small increase in cancer mortality. More recently in a 25-year follow-up of military personnel who served in the French Navy, there was no increase in all-cause or cancer mortality for personnel exposed to radar [ 125 ]. The main limitation in the cohort studies was the lack of individual levels of RF exposure with most studies based on job-title. Comparisons were made between occupations with presumed high exposure to RF fields and other occupations with presumed lower exposure. This type of non-differential misclassification in dichotomous exposure assessment is associated mostly with an effect measure biased towards a null effect if there is a true effect of RF fields. If there is no true effect of RF fields, non-differential exposure misclassification will not bias the effect estimate (which will be close to the null value, but may vary because of random error). The military personnel in these studies were compared with the general population and this ‘healthy worker effect’ presents possible bias since military personnel are on average in better health than the general population; the healthy worker effect tends to underestimate the risk. The cohort studies also lacked information on possible confounding factors including other occupational exposures such as chemicals and lifestyle factors such as smoking.

Several epidemiological studies have specifically investigated radar exposure and testicular cancer. In a case-control study where most of the subjects were selected from military hospitals in Washington DC, USA, Hayes et al. found no increased risk between exposure to radar and testicular cancer [ 126 ]; exposure to radar was self-reported and thus subject to misclassification. In this study, the misclassification was likely non-differential, biasing the result towards the null. Davis and Mostofi reported a cluster of testicular cancer within a small cohort of 340 police officers in Washington State (USA) where the cases routinely used handheld traffic radar guns [ 127 ]; however, exposure was not assessed for the full cohort, which may have overestimated the risk. In a population-based case-control study conducted in Sweden, Hardell et al. did not find a statistically significant association between radar work and testicular cancer; however, the result was based on only five radar workers questioning the validity of this result [ 128 ]. In a larger population-based case control study in Germany, Baumgardt-Elms et al. also reported no association between working near radar units (both self-reported and expert assessed) and testicular cancer [ 129 ]; a limitation of this study was the low participation of identified controls (57%), however, there was no difference compared with the characteristics of the cases so selection bias was unlikely. In the cohort study of US navy veterans previously mentioned exposure to radar was not associated with testicular cancer [ 122 ]; the limitations of this cohort study mentioned earlier may have underestimated the risk. Finally, in a hospital-based case-control study in France, radar workers were also not associated with risk of testicular cancer [ 130 ]; a limitation was the low participation of controls (37%) with a difference in education level between participating and non-participating controls, which may have underestimated this result.

A limited number of studies have investigated radar exposure and brain cancer. In a nested case-control study within a cohort of male US Air Force personnel, Grayson reported a small association between brain cancer and RF exposure, which included radar [ 131 ]; no potential confounders were included in the analysis, which may have overestimated the result. However, in a case-control study of personnel in the Brazilian Navy, Santana et al. reported no association between naval occupations likely to be exposed to radar and brain cancer [ 132 ]; the small number of cases and lack of diagnosis confirmation may have biased the results towards the null. All of the cohort studies on military personnel previously mentioned also examined brain cancer mortality and found no association with exposure to radar [ 122 , 124 , 125 ].

A limited number of studies have investigated radar exposure and ocular cancer. Holly et al. in a population-based case-control study in the US reported an association between self-reported exposure to radar or microwaves and uveal melanoma [ 133 ]; the study investigated many different exposures and the result is prone to multiple testing. In another case-control study, which used both hospital and population controls, Stang et al. did not find an association between self-reported exposure to radar and uveal melanoma [ 134 ]; a high non-response in the population controls (52%) and exposure misclassification may have underestimated this result. The cohort studies of the Belgian military and French navy also found no association between exposure to radar and ocular cancer [ 124 , 125 ].

A few other studies have examined the potential association between radar and other cancers. In a hospital-based case-control study in Italy, La Vecchia investigated 14 occupational agents and risk of bladder cancer and found no association with radar, although no risk estimate was reported [ 135 ]; non-differential self-reporting of exposure may have underestimated this finding if there is a true effect. Finkelstein found an increased risk for melanoma in a large cohort of Ontario police officers exposed to traffic radar and followed for 31 years [ 136 ]; there was significant loss to follow up which may have biased this result in either direction. Finkelstein found no statistically significant associations with other types of cancer and the study reported a statistically significant risk estimate just below unity for all cancers, which is reflective of the healthy worker effect [ 136 ]. In a large population-based case-control study in France, Fabbro-Peray et al. investigated a large number of occupational and environmental risk factors in relation to non-Hodgkin lymphoma and found no association with radar operators based on job-title; however, the result was based on a small number of radar operators [ 137 ]. The cohort studies on military personnel did not find statistically significant associations between exposure to radar and other cancers [ 122 , 124 , 125 ].

Variani et al. conducted a recent systematic review and meta-analysis investigating occupational exposure to radar and cancer risk [ 138 ]. The meta-analysis included three cohort studies [ 122 , 124 , 125 ] and three case-control studies [ 129 , 130 , 131 ] for a total sample size of 53,000 subjects. The meta-analysis reported a decrease in cancer risk for workers exposed to radar but noted the small number of studies included with significant heterogeneity between the studies.

Apart from cancer, a number of epidemiological studies have investigated radar exposure and reproductive outcomes. Two early studies on military personnel in the US [ 139 ] and Denmark [ 140 ] reported differences in semen parameters between personnel using radar and personnel on other duty assignments; these studies included only volunteers with potential fertility concerns and are prone to bias. A further volunteer study on US military personnel did not find a difference in semen parameters in a similar comparison [ 141 ]; in general these type of cross-sectional investigations on volunteers provide limited evidence on possible risk. In a case-control study of personnel in the French military, Velez de la Calle et al. reported no association between exposure to radar and male infertility [ 142 ]; non-differential self-reporting of exposure may have underestimated this finding if there is a true effect. In two separate cross-sectional studies of personnel in the Norwegian navy, Baste et al. and Møllerløkken et al. reported an association between exposure to radar and male infertility, but there has been no follow up cohort or case control studies to confirm these results [ 143 , 144 ].

Again considering reproduction, a number of studies investigated pregnancy and offspring outcomes. In a population-based case-control study conducted in the US and Canada, De Roos et al. found no statistically significant association between parental occupational exposure to radar and neuroblastoma in offspring; however, the result was based on a small number of cases and controls exposed to radar [ 145 ]. In another cross-sectional study of the Norwegian navy, Mageroy et al. reported a higher risk of congenital anomalies in the offspring of personnel who were exposed to radar; the study found positive associations with a large number of other chemical and physical exposures, but the study involved multiple comparisons so is prone to over-interpretation [ 146 ]. Finally, a number of pregnancy outcomes were investigated in a cohort study of Norwegian navy personnel enlisted between 1950 and 2004 [ 147 ]. The study reported an increase in perinatal mortality for parental service aboard fast patrol boats during a short period (3 months); exposure to radar was one of many possible exposures when serving on fast patrol boats and the result is prone to multiple testing. No associations were found between long-term exposure and any pregnancy outcomes.

There is limited research investigating exposure to radar and other diseases. In a large case-control study of US military veterans investigating a range of risk factors and amyotrophic lateral sclerosis, Beard et al. did not find a statistically significant association with radar [ 148 ]; the study reported a likely under-ascertainment of non-exposed cases, which may have biased the result away from the null. The cohort studies on military personnel did not find statistically significant associations between exposure to radar and other diseases [ 122 , 124 , 125 ].

A number of observational studies have investigated outcomes measured on volunteers in the laboratory. They are categorised as epidemiological studies because exposure to radar was not based on provocation. These studies investigated genotoxicity [ 149 ], oxidative stress [ 149 ], cognitive effects [ 150 ] and endocrine function [ 151 ]; the studies generally reported positive associations with radar. These volunteer studies did not sample from a defined population and are prone to bias [ 152 ].

The experimental studies investigating exposure to MMWs at levels below the ICNIRP occupational limits have looked at a variety of biological effects. Genotoxicity was mainly examined by using comet assays of exposed cells. This approach has consistently found no evidence of DNA damage in skin cells in well-designed studies. However, animal studies conducted by one research group reported DNA strand breaks and changes in enzymes that control the build-up of ROS, noting that these studies had low animal numbers (six animals exposed); these results have not been independently replicated. Studies have also investigated other indications of genotoxicity including chromosome aberrations, micro-nucleation and spindle disturbances. The methods used to investigate these indicators have generally been rigorous; however, the studies have reported contradictory results. Two studies by a Russian research group have also reported indicators of DNA damage in bacteria, however, these results have not been verified by other investigators.

The studies of the effect of MMWs on cell proliferation primarily focused on bacteria, yeast cells and tumour cells. Studies of bacteria were mainly from an Armenian research group that reported a reduction in the bacterial growth rate of exposed E. coli cells at different MMW frequencies; however, the studies suffered from inadequate dosimetry and temperature control and heating due to high RF energy deposition may have contributed to the results. Other authors have reported no effect of MMWs on E. coli cell growth rate. The results on cell proliferation of yeast exposed to MMWs were also contradictory. An Italian research group that has conducted the majority of the studies on tumour cells reported either a reduction or no change in the proliferation of exposed cells; however, these studies also suffered from inadequate dosimetry and temperature control.

The studies on gene expression mainly examined two different indicators, expression of stress sensitive genes and chaperone proteins and the occurrence of a resonance effect in cells to explain DNA conformation state changes. Most studies reported no effect of low-level MMWs on the expression of stress sensitive genes or chaperone proteins using a range of experimental methods to confirm these results; noting that these studies did not use blinding so experimental bias cannot be excluded from the results. A number of studies from a Russian research group reported a resonance effect of MMWs, which they propose can change the conformation state of chromosomal DNA complexes. Their results relied heavily on the AVTD method for testing changes in the DNA conformation state, however, the biological relevance of results obtained through the AVTD method has not been independently validated.

Studies on cell signalling and electrical activity reported a range of different outcomes including increases or decreases in signal amplitude and changes in signal rhythm, with no consistent effect noting the lack of blinding in most of the studies. Further, temperature contributions could not be eliminated from the studies and in some cases thermal interactions by conventional heating were studied and found to differ from the MMW effects. The results from some studies were based on small sample sizes, some being confined to a single specimen, or by observed effects only occurring in a small number of the samples tested. Overall, the reported electrical activity effects could not be dismissed as being within normal variability. This is indicated by studies reporting the restoration of normal function within a short time during ongoing exposure. In this case there is no implication of an expected negative health outcome.

Studies on membrane effects examined changes in membrane properties and permeability. Some studies observed changes in transitions from liquid to gel phase or vice versa and the authors implied that MMWs influenced cell hydration, however the statistical methods used in these studies were not described so it is difficult to examine the validity of these results. Other studies observing membrane properties in artificial cell suspensions and dissected tissue reported changes in vesicle shape, reduced cell volume and morphological changes although most of these studies suffered from various methodological problems including poor temperature control and no blinding. Experiments on bacteria and yeast were conducted by the same research group reporting changes in membrane permeability, which was attributed to cell proliferation effects, however, the studies suffered from inadequate dosimetry and temperature control. Overall, although there were a variety of membrane bioeffects reported, these have not been independently replicated.

The limited number of studies on a number of other effects from exposure to MMWs below the ICNIRP limits generally reported little to no consistent effects. The single in vivo study on cancer promotion did not find an effect although the study did not include sham controls. Effects on reproduction were contradictory that may have been influenced by opposing objectives of examining adverse health effects or infertility treatment. Further, the only study on human sperm found no effects of low-level MMWs. The studies on reproduction suffered from inadequate dosimetry and temperature control, and since sperm is sensitive to temperature, the effect of heating due to high RF energy deposition may have contributed to the studies showing an effect. A number of studies from two research groups reported effects on ROS production in relation to reproduction and immune function; the in vivo studies had low animal numbers (six animals per exposure) and the in vitro studies generally had inadequate dosimetry and temperature control. Studies on fatty acid composition and physiological indicators did not generally show any effects; poor temperature control was also a problem in the majority of these studies. A number of other studies investigating various other biological effects reported mixed results.

Although a range of bioeffects have been reported in many of the experimental studies, the results were generally not independently reproduced. Approximately half of the studies were from just five laboratories and several studies represented a collaboration between one or more laboratories. The exposure characteristics varied considerably among the different studies with studies showing the highest effect size clustered around a PD of approximately 1 W/m 2 . The meta-analysis of the experimental studies in our companion paper [ 9 ] showed that there was no dose-response relationship between the exposure (either PD or SAR) and the effect size. In fact, studies with a higher exposure tended to show a lower effect size, which is counterfactual. Most of the studies showing a large effect size were conducted in the frequency range around 40–55 GHz, representing investigations into the use of MMWs for therapeutic purposes, rather than deleterious health consequences. Future experimental research would benefit from investigating bioeffects at the specific frequency range of the next stage of the 5 G network roll-out in the range 26–28 GHz. Mobile communications beyond the 5 G network plan to use frequencies higher than 30 GHz so research across the MMW band is relevant.

An investigation into the methods of the experimental studies showed that the majority of studies were lacking in a number of quality criteria including proper attention to dosimetry, incorporating positive controls, using blind evaluation or accurately measuring or controlling the temperature of the biological system being tested. Our meta-analysis showed that the bulk of the studies had a quality score lower than 2 out of a possible 5, with only one study achieving a maximum quality score of 5 [ 9 ]. The meta-analysis further showed that studies with a low quality score were more likely to show a greater effect. Future research should pay careful attention to the experimental design to reduce possible sources of artefact.

The experimental studies included in this review reported PDs below the ICNIRP exposure limits. Many of the authors suggested that the resulting biological effects may be related to non-thermal mechanisms. However, as is shown in our meta-analysis, data from these studies should be treated with caution because the estimated SAR values in many of the studies were much higher than the ICNIRP SAR limits [ 9 ]. SAR values much higher than the ICNIRP guidelines are certainly capable of producing significant temperature rise and are far beyond the levels expected for 5 G telecommunication devices [ 1 ]. Future research into the low-level effects of MMWs should pay particular attention to appropriate temperature control in order to avoid possible heating effects.

Although a systematic review of experimental studies was not conducted, this paper presents a critical appraisal of study design and quality of all available studies into the bioeffects of low level MMWs. The conclusions from the review of experimental studies are supported by a meta-analysis in our companion paper [ 9 ]. Given the low-quality methods of the majority of the experimental studies we infer that a systematic review of different bioeffects is not possible at present. Our review includes recommendations for future experimental research. A search of the available literature showed a further 44 non-English papers that were not included in our review. Although the non-English papers may have some important results it is noted that the majority are from research groups that have published English papers that are included in our review.

The epidemiological studies on MMW exposure from radar that has a similar frequency range to that of 5 G and exposure levels below the ICNIRP occupational limits in most situations, provided little evidence of an association with any adverse health effects. Only a small number of studies reported positive associations with various methodological issues such as risk of bias, confounding and multiple testing questioning the result. The three large cohort studies of military personnel exposed to radar in particular did not generally show an association with cancer or other diseases. A key concern across all the epidemiological studies was the quality of exposure assessment. Various challenges such as variability in complex occupational environments that also include other co-exposures, retrospective estimation of exposure and an appropriate exposure metric remain central in studies of this nature [ 153 ]. Exposure in most of the epidemiological studies was self-reported or based on job-title, which may not necessarily be an adequate proxy for exposure to RF fields above 6 GHz. Some studies improved on exposure assessment by using expert assessment and job-exposure matrices, however, the possibility of exposure misclassification is not eliminated. Another limitation in many of the studies was the poor assessment of possible confounding including other occupational exposures and lifestyle factors. It should also be noted that close proximity to certain very powerful radar units could have exceeded the ICNIRP occupational limits, therefore the reported effects especially related to reproductive outcomes could potentially be related to heating.

Given that wireless communications have only recently started to use RF frequencies above 6 GHz there are no epidemiological studies investigating 5 G directly as yet. Some previous epidemiological studies have reported a possible weak association between mobile phone use (from older networks using frequencies below 6 GHz) and brain cancer [ 11 ]. However, methodological limitations in these studies prevent conclusions of causality being drawn from the observations [ 152 ]. Recent investigations have not shown an increase in the incidence of brain cancer in the population that can be attributed to mobile phone use [ 154 , 155 ]. Future epidemiological research should continue to monitor long-term health effects in the population related to wireless telecommunications.

The review of experimental studies provided no confirmed evidence that low-level MMWs are associated with biological effects relevant to human health. Many of the studies reporting effects came from the same research groups and the results have not been independently reproduced. The majority of the studies employed low quality methods of exposure assessment and control so the possibility of experimental artefact cannot be excluded. Further, many of the effects reported may have been related to heating from high RF energy deposition so the assertion of a ‘low-level’ effect is questionable in many of the studies. Future studies into the low-level effects of MMWs should improve the experimental design with particular attention to dosimetry and temperature control. The results from epidemiological studies presented little evidence of an association between low-level MMWs and any adverse health effects. Future epidemiological research would benefit from specific investigation on the impact of 5 G and future telecommunication technologies.

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This work was supported by the Australian Government’s Electromagnetic Energy Program. This work was also partly supported by National Health and Medical Research Council grant no. 1042464. 

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Karipidis, K., Mate, R., Urban, D. et al. 5G mobile networks and health—a state-of-the-science review of the research into low-level RF fields above 6 GHz. J Expo Sci Environ Epidemiol 31 , 585–605 (2021). https://doi.org/10.1038/s41370-021-00297-6

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5g technology essay 250 words

The first generation of technology, which enables us to make voice calls, was introduced in the 1980s and was based on analog radio transmissions. This technology was launched. Then, in the 1990s, 2G was introduced, which is built on the digital version of radio signals and can assist us in both the transfer of data and with a lower bandwidth requirement. 

The third-generation mobile network, or 3G, was introduced in the 2000s. It is capable of delivering a data transfer speed of one to two megabits per second to us, and it also enables us to make video conversations. The most recent iteration of 4G, which debuted in 2009, is capable of delivering bandwidth of 100 Mbps to 1 Gbps and performs quite well in virtual reality.

The next generation of mobile broadband, known as 5G Technology, will eventually supersede or, at the very least, increase the capabilities of 4G LTE connections. LTE, which stands for “long-term development,” is a standard for wireless broadband communications that can be used by mobile devices and data terminals.

The fifth-generation wireless network, also known as 5G, is a game-changing innovation in the realm of telecommunications. In the near future, this technology will be used in place of 4G, and it will play a role in the communication industry that has never been seen before. This technology was first developed in the southern hemisphere, and it is now also being implemented in India.  This will provide a significant boost to important programs in India’s social, economic, defense, and space sectors, among others, thereby accelerating the nation’s overall rate of development.

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Essay on 5g technology 300 words

The transmission of signals for the 5G network will not require any kind of tower; instead, the transmission of signals through small cell stations can be placed on rooftops or electric poles. As a direct result of the millimetre-wave spectrum, the significance of these minor cells has dramatically increased.

It is planned to make use of a wide variety of cutting-edge technologies that fall under the category of 5G technologies. These technologies include MIMO, TDD, and others. The Multiple Input Multiple Output (MIMO) technology will be able to deliver a downloading capability, including an intensity of around 952 Mbps. The first generation of technology, known as 1G, was introduced in the 1980s. It was dependent on analog radio transmissions and could only handle voice communications.

The second-generation technology, or 2G, was introduced in the 1990s. It was based on digital radio signals and permitted the transmission of voice calls as well as data at a bandwidth of 64 kilobits per second. In the 2000s, the third-generation (3G) technology was introduced with a transmission speed ranging from one megabit per second (Mbps) to two megabits per second (Mbps), and it was able to send telephone signals such as digitized voice calls, video calls, and conferencing.

The fourth-generation cellular network, or 4G Technology, was introduced in 2009 with a peak speed ranging from 100 megabits per second to one gigabit per second. It also supports 3D virtual reality. There are indeed issues linked to infrastructure, investment, and health in relation to 5G technology in India right now; however, the government should overcome these challenges as soon as feasible and deploy this technology in India.  As a result of India’s adoption of 5G technology, the country’s economic, socio-strategic, and other sectors are going to experience a surge of vitality, and the country’s overall progress will be pushed even further.

5g technology essay 500 words

INTRODUCTION

The fifth generation of mobile broadband, or 5G, is currently under development. It is eventually going to take the place of the existing 4G LTE mobile broadband connection. Download speeds that are exponentially quicker than before. Increased uploading and downloading speeds. It is anticipated that latency will significantly improve. (The amount of time that passes while wireless devices are attempting to communicate with a wireless network is referred to as ‘latency.’)

EXCEPTIONAL RATES OF DATA TRANSFER

This new generation of technology has a data transfer or network speed of roughly 20 gigabytes per second, making it significantly faster than any of the previous generations. We can obtain this data or network speed if we use this new technology.  Because of this, we are able to either download or upload files at a speed of 10 gigabytes per second (GB/s), which is very quick; furthermore, because of this, we are able to quickly do our work at a very quick pace.

PROGRESS IN THE FIELD OF DIGITAL TECHNOLOGY

We are able to make rapid strides forward in a variety of digital fields in our nation of India thanks to this cutting-edge new technology, which will also help our country’s overall development efforts.  Because of the speed at which it operates and the variety of characteristics it possesses, we are able to observe the beginning of a new era of technology, either in a contemporary manner or within the context of the wireless component of our progression.

EXCEPTIONALLY HIGH LEVELS OF CONNECTEDNESS THROUGHOUT THE BOARD

The connections that we are able to form via the use of this new technology are also going to be of assistance to us, which is something that cannot be said about any technology that was developed in previous generations.  We can handle up to one million connections per square kilometer, which is really astounding much like the internet speed of this technology that I said earlier in my essay about 5G technology.

EXCEPTIONALLY LOW LEVELS OF LATENCY

This technology not only gives you access to the quickest Speed for data transfer, but it also gives you access to very low latency. This latency is a phrase that is used to describe the speed required to deliver a whole data packet from one device to another device.  This speed, which can take up to one millisecond and is required for all tasks relating to this technology, is referred to as latency.

THE ADVANTAGES THAT CAN BE GAINED FROM USING 5G TECHNOLOGY

As a result of the fact that technological progress is essential, as we discussed in the section of this essay devoted to 5G technology titled “5G Will Provide a High Internet Speed as well as a Better and More Secure Network to Transmit Data on a Large Scale,” 5G will deliver not only a faster internet connection but also an improved and much more. This 5th generation of technology also offers low latency for the transmission of data packets from one device to another device with the assistance of various applications. The latency offered by this technology, which is mostly 1 millisecond, is significantly lower than the latency offered by the 4th generation of technology, which was 50 milliseconds.

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