Wireless connectivity has become part and parcel of our society nowadays. More than 50 billion connected devices will be using the cellular network services by the end of the year 2020. This encourages the development of 5G networks because of tremendous increase in data traffic, as compared to 2014. A spectrum shortage problem arises because of increasing traffic number in different sectors.The existing technology may not support the upcoming huge demands whereas millimeter wave (mmWave) band with huge bandwidth 30 GHz to 300 GHz will be an important part of the 5G Wireless communication system.Current researches are focused on the 28 GHz band and 38 GHz while there is a huge spectrum. The other bands 60 GHz and E-bands (71-76 GHz to 81-86 GHz) have many advantages like narrow beamforming capability and high data transmission rate with huge capacity.Cellular access , wireless backhaul and small cell access are the efficient applications of mmWave for 5G. 5G mmwave wireless channel bandwidths will be more than ten times greater than today's 4G Long-Term Evolution 20 MHz cellular channels. Channel models are required for simulating propagation in a reproducible and cost-efficient way are used to design and compare radio air interfaces and system development accurately.
The first generation (1G) mobile wireless communication network was analogy used for voice calls only. It was developed in 1970-1980 with a data bandwidth of 2 Kbps. With issues in quality and security of data transmitted, researchers and developers worked harder to overcome the short comings of 1G and that eventually gave birth to digital systems and signals.
The process of converting analogy to digital signals manifested a significant change and this marked the beginning of the second generation (2G) in the field of telecommunications. With technologies like GSM and CDMA , not only communications over long distances with better voice transfer capabilities was achieved but the users could also send text and picture messages to another user. By the end of the second millennium, users could even send emails within a secured framework.
After a decade of 2G, the demand for high data transfer increased which led to a new generation of wireless telecommunications which is used in many countries even today. The third generation (3G) enabled users to carry out video calls, stream live TV, faster downloads and the capability of uploading and sending larger files across the globe. Global roaming facility was also provided. Commercialized by 2007 with a speed of 2 Mbps, 3G helped enhance the new generation of cellular phones or smart phones as we normally call them.
The fourth-generation technology provides the same features as 3G with a few additional services but the extraordinary increase of downloading speed from 2 Mbps to 100 Mbps urged the telecommunication giants to mark this advancement as a new generation altogether. The reason for such high speeds was needed keeping in mind the requirement of internet usage in motion. For example, Aeroplanes , Bullet trains etc require a stable internet connection while travelling at high speed and altitude. 4G requires expensive and complicated hardware and with the advent of 5G, this technology will be around for many years to come.
1 to 4G
What developed first was first generation and termed as 1G and further notable innovations in the field of wireless technology were denoted with an increase of integer in the prefix.
1G
The first generation (1G) mobile wireless communication network was analogy used for voice calls only. It was developed in 1970-1980 with a data bandwidth of 2Kbps. With issues in quality and security of data transmitted, researchers and developers worked harder to overcome the short comings of 1G and that eventually gave birth to digital systems and signals.
2G
The process of converting analogy to digital signals manifested a significant change and this marked the beginning of the second generation (2G) in the field of telecommunications. With technologies like GSM and CDMA, not only communications over long distances with better voice transfer capabilities was achieved but the users could also send text and picture messages to another user. By the end of the second millennium, users could even send emails within a secured framework.
3G
After a decade of 2G, the demand for high data transfer increased which led to a new generation of wireless telecommunications which is used in many countries even today. The third generation (3G) enabled users to carry out video calls, stream live TV, faster downloads and the capability of uploading and sending larger files across the globe. Global roaming facility was also provided. Commercialized by 2007 with a speed of 2Mbps, 3G helped enhance the new generation of cellular phones or smart phones as we normally call them.
4G
The fourth-generation technology provides the same features as 3G with a few additional services but the extraordinary increase of downloading speed from 2mbps to 100Mbps urged the telecommunication giants to mark this advancement as a new generation altogether. The reason for such high speeds was needed keeping in mind the requirement of internet usage in motion. For example, Aeroplanes, Bullet trains etc require a stable internet connection while travelling at high speed and altitude. 4G requires expensive and complicated hardware and with the advent of 5G, this technology will be around for many years to come.
5g is the fifth generation of wireless technology. it will let a person to carry out all the usual activities done on a cellular device but with an unimaginable speed. this incredible speed will also open doors into a new dimension of internet technology never experienced before. not only will it allow users to browse websites created on virtual reality, upload or download ultra hd videos, and use data-intensive apps or features but also it will allow the user to connect a major chunk of the devices used in home and thus transforming it into a smart house and all that without a bit of latency. in a more technical sense, 5g brings three new aspects to the table: greater speed (to move more data), lower latency (to be more responsive), and the ability to connect a lot more devices at once (smart homes with smart devices).
While research and development in 5G technology began in 2008, however, the technology was first tested successfully in 2018 by Korea telecom in 2018 winter Olympics. AT&T and Verizon carried out the tests in a few cities in U.S while Vodafone initiated in the U.K in April 2018. 5G technology would launch out globally in 2019 with many compatible devices being launched in the first half of the year. The earliest 5G deployments have used fixed wireless, like the wireless broadband used at home due to the adoption of millimeter wave technology which require multiple small celled towers in an area rather than a single traditional cellular tower. The installation of several towers to cover a small area require huge capital investment and time. By 2020, a considerable number of people would be using 5G across the globe. According to Ericsson, a company that makes some of the cellular infrastructure, there will be over 1.5 billion of us connected to 5G by 2024.
The global rat race for implementing 5G is on! With fierce competition among most of the countries, experiencing 5 G will soon come out from theory to reality. The Super powers have already implemented test phases in a few cities with others not lagging behind.
The following countries have initiated 5G with a limited scope:
USA
China
Russia
UK
France
Countries like South Korea, Germany, Japan have also started investing heavily in 5g infrastructure.
The first thought that often comes to our mind is would my current phone become a brick once 5G launches. The answer is not at all. Though 5G would be available by 2019 but it would require many more years for a complete migration from 4G to 5G network as it requires huge costs. In the initial phase the Telecom companies will rollout 5G gradually from urban cities to smaller towns. More than 10 cellular device manufacturers globally have pledged a 5G phone in 2019. The more famous ones include:
Supported Devices:
Samsung
LG
HTC
OnePlus
Nokia
Huawei
Xiaomi
Vivo
Sony
Asus
The world is moving mobile and data consumption is rising exponentially every year, particularly as streaming videos and audios online is gaining popularity. The existing 4G has the capability of providing a faster internet but when it comes to the number of users, interruptions in service, specially when lots of people in the same area are trying to access online mobile services at the same time. To overcome this drawback, 5G is much better at handling thousands of devices at the same time, from mobiles to equipment sensors, video cameras to smart street lights.
The biggest noticeable benefits will be speed. 5G is expected to deliver somewhere between 80-100Mbps which means getting the wired broadband like speed on the move. That’s going to make a vast change when it comes to downloading movies, large files, or playing games. Movie would be streaming as seamlessly as music streaming currently is dropping the requirement of storage devices. The augmented reality experiences which are currently theorized could become reality, PC-quality gaming on your mobile with “zero lag” or having multi-way video calling without any issues.
One of the most important development talked upon the implementation of 5G is to bring into reality the concept of automated cars. The first generation of driverless cars will be self-contained, but future generations will interact with other cars and smart roads to improve safety and manage traffic. The concept here is that everything on the road would be talking to everything else and to do this impeccably, the principal requirement is minimum possible latency. All the cars would be exchanging very small packets of information almost instantly. That’s where 5G’s sub-one-millisecond latency comes into play, when a packet of data shoots directly between two cars or bounces from a car to a small cell on a lamp post to another car.
There would be developments which we cannot foresee but imagine drones carrying out search and rescue missions, fire assessments and traffic monitoring, with wireless communication taking place flawlessly with each other and ground base stations over 5G networks. It would bring big changes to video games, sports and shopping. Hospitals can create massive sensor networks to monitor patients, physicians can prescribe smart pills to track compliance, and insurers can even monitor subscribers to determine appropriate treatments and processes.
Beyond general consumer needs, a 5G network will also allow a connected traffic infrastructure, smart communities and cities, industrial IoT where remote factories working without local intervention and immersive education—all relying on 5G.