The Evolution of Mobile Networks from 5G to 6G

Owing to the ever-increasing demand for faster communication networks, the rise of a new 6G technology is expected in the near future. The 6th-generation mobile communication network is expected to further improve and enhance the already existing networks.

The advancements seen over the years have evolved dramatically from 1G to 2G, which initially were voice-based but progressed further to text messages. 3G evolution enabled users to exchange multimedia information such as videos, music, and images. 4th Gen ensured a high data communication rate of over 100Mbps, thus leading to the popularization of smartphone use. Further technological advancements made the 5th Gen come to fruition.

In contrast with 4G networks, 5G networks can provide a data rate of 20GBPS, with the end-to-end latency being only 10ms. 6G can provide a data rate of up to 1TBPS. The 6G networks are envisioned to have ultra-low latency and intend to improve the capacity by 1000 times through the means of terahertz frequency and spatial multiplexing. Moreover, there are three bands for 6G networks:

• ubiquitous mobile ultra-broadband (uMUB),
• ultrahigh-speed-with-low-latency communications (uHSLLC), and
• ultrahigh data density(uHDD).

Privacy and security will be most important in the 6G era. With the digital landscape becoming highly complex, advanced encryption methods and authentication mechanisms may be incorporated to ensure the integrity and confidentiality of communication. Besides all these, 6G could make way for the Internet of Senses (IoS), where augmented reality, virtual reality, and other sensory technologies are effortlessly integrated into daily experiences. 6G networks are expected to provide a reliability percentage of 99.9. Most of the 6G use cases will eventually surface from the quality of experience and emerging functionalities of the 5G system-based applications.

When can we expect a fully functional 6G network?

The applications of 6G networks will advance further by performance enhancement measures. 6G networks should be based on a human-centric approach instead of data-centric approaches to keep up with the upcoming demands. The coverage provided by 6G can be extended extensively through the proper integration of other technologies. Though the discussions about defining 6G network requirements began in 2020, it will take almost a decade to launch it in a fully operational mode throughout the world. 6G will have profound applications in various sectors, such as healthcare, facial recognition, and accurate decision-making, thus having long-term implications for government and industry approaches.

During the last decade, a significant surge has been observed in mobile data traffic, mainly due to the advent of smart devices. This being taken into studies, the worldwide mobile traffic volume is expected to increase 700 times by the year 2030. To top it all, the International Telecommunication Union has predicted that the overall mobile data traffic is expected to cross the 5ZB per month mark, with the number of mobile subscriptions reaching 17.1 billion by the year 2030. Despite 5G networks being highly potent, they don't suffice to meet the requirements of the recently surfaced smart applications. Hence, 6G is being envisioned to overcome the significant bottlenecks in the existing 5G network.

Why 6G?

A 6G network can be defined as a cellular network that uses cognitive technologies and operates in untapped radio frequencies to enable low-latency communication at high speed, faster than the existing generations. Subsequent generations use much more sophisticated digital encoding that the outdated computers cannot achieve. Their dependence lies on broader airwave bands that weren't previously made accessible by governments. According to a report, the standard for 6G will likely be finished by 2030, when the first set of 6G devices will be available. Deployment will be close to ubiquitous by the year 2030.

A significant portion of 6G will be emphasized on transferring waves in the THz range. Though these waves will be minuscule and fragile, they free up a massive spectrum, thus allowing unbelievable data transfer speeds. Currently, wireless technologies permit transmission or reception at the same time only on specific frequencies. 6G is looked after to boost the efficiency of current spectrum delivery using mathematics to receive and transmit on the same frequency simultaneously. 6G will use machines in the form of amplifiers to allow each device to expand coverage. Besides surpassing 5G, 6G will support an array of unique features to establish next-gen wireless communication models. It will integrate, combine, and correlate different technologies, such as deep learning with big data analytics.

The majority of IoT and other high-tech developments will require 6G as an essential component. For 6G, the newest pioneer spectrum slabs are anticipated to be in mid-bands 7-20GHz. This would facilitate lower bands for extensive coverage and sub-THz bands for peak data speeds. The usage of a broad spectrum will push localization to the next level, including spectral ranges in terahertz. This higher spectral efficiency will offer users instant access to the services they seek. Since the latency will be reduced to nearly less than 0.1 milliseconds, real-time applications' performance will be greatly enhanced. Moreover, decreased latency will facilitate emergency responses, remote surgical procedures, and industrial automation.

Further, 6G will enable the effortless execution of delay-sensitive real-time applications by making the network many times more dependable than the already existing 5G. The advent of 6G will enable 10 million linked devices per square kilometer. 6G networks will require more vital radio frequencies to meet the requirement for greater bandwidth. As 6G will optimize M2M interactions by increasing network dependability, it will be far better than 5G in terms of network stability and penetration. 6G networks are also anticipated to be implemented in heterogeneous cloud settings, including a combination of private, public, and hybrid. AI/ML combined with 6G will assist in achieving superior efficiency at reduced computational complexities.

6G networks will generate comparatively more data in contrast with 5G networks, which will cause data centers to evolve. Furthermore, media access control (MAC) and physical (PHY) layers will be virtualized. This will reduce the expenses for networking equipment. Another significant advantage of 6G networks is their vast coverage area, which covers space with fewer towers. There will be reduced interference between devices, providing improved and efficient services. Despite major cellular traffic being produced indoors, cellular networks were never built to target indoor coverage appropriately. 6G networks will overcome these obstacles using small cell sites and distributed antenna systems. 6G will be able to provide access points serving multiple clients simultaneously through orthogonal frequency-division multiple access. 6G will be suited to make greater use of distributed radio access networks to increase capacity and improve spectrum sharing.

The entertainment industry will also greatly benefit from the 6G network as more users will have access to streaming sites on multiple devices, such as laptops, mobiles, and tablets. This will further result in an increase in the number of streaming subscriptions and motivate more users to use apps and websites for entertainment and vacationing purposes. 6G will eliminate the temporal and physical distance between users through various innovative applications in holographic imaging and wireless connectivity. 6G will also feasibly enable instant communication devoid of latencies, leading to omnichannel connectivity between the digital and physical worlds.

5G to 6G migration:

Owing to higher frequency and higher sampling rates, 6G will provide a significantly better throughput and higher data rates. The usage of frequency selectivity for the determination of relative EM absorption rates and wavelengths lesser than 1mm will boost the development of wireless sensing technology. With time, as 6G becomes operational, core computing will be integrated, thus making 6G more potent. This will also provide better and improved access to AI capabilities and support for high-end mobile devices and systems. It will offer lesser energy consumption, higher coverage, and cost-effectiveness.

Challenges involved:

1. Technology limitations: Developing the essential hardware and infrastructure to support the advanced features of 6G is a major challenge. This includes developing efficient signal processing capabilities, efficient antennas, and network components that can handle ultra-high data rates and ultra-low latency.

2. Energy efficiency: Since 6G networks are expected to handle massive data traffic and support innumerable connected devices, energy efficiency becomes a huge challenge. The development of energy-efficient hardware, power management techniques, and sustainable network designs is essential to minimize environmental impact and other costs involved.

3. Spectrum allocation: The availability and allocation of suitable frequency bands for 6G networks is one of the biggest challenges. Since higher frequencies are involved in 6G, it is important to ensure sufficient spectrum resources and manage interference issues. 6G is expected to use the THz spectrum, which has a wider bandwidth and can also support high data rates with low latency. However, THz waves can be easily absorbed by atmospheric oxygen and water vapor, thus limiting their transmission range.

4. Heterogeneous networks: 6G is supposed to use a heterogeneous network (HetNet) architecture, which will combine different types of wireless networks, such as wi-fi networks, cellular networks, and satellite networks. Being complex to manage, these require new protocols and algorithms.

5. Standardization: 6G still being in the early stages of development, there is no agreed-upon standard for the technology. Thus, it will take considerable time to deploy, develop, and maintain 6G networks.

6. Regulatory and policy frameworks: Apt regulatory and policy frameworks are required to govern and deploy 6G networks. This includes privacy regulations, intellectual property rights, spectrum management, and assessing potential societal impacts. The creation of an innovative and competitive environment while safeguarding public interest is a significant challenge.

7. New materials and devices: For 6G, it will be necessary to manufacture new devices that can operate at THz frequencies as per the requirement. It is a big challenge to make such devices that can withstand high power levels and high temperatures.

8. Ethical and social considerations: Concerns pertaining to potential job displacement, data privacy, algorithm bias, and equitable access to advanced services need to be addressed.

9. Network architecture and integration: Ensuring efficient interworking between different network elements and optimizing network performance is critical. Hence, designing a scalable and sturdy network architecture that can effortlessly integrate various technologies such as satellite communications, heterogeneous networks, and edge computing is a challenge.

   Other than the challenges mentioned above, developing advanced authentication protocols, encryption techniques, and intrusion detection systems to provide cybersecurity and safeguard user data is a major challenge. Since 6G would be implemented in innumerable applications such as healthcare, banking, and finance, it would be secure and private. Besides, post-deployment, 6G networks need to be accepted by the public, for which concerns pertaining to privacy and security need to be addressed on a large scale.

   Cost Impact:

   6G network will enable joint communication, localization, and sensing to address the needs of industries in a single system, thus reducing overall costs. However, with the surge in costs for deployment of dense networks requiring an increasing number of base stations, mobile operators are more intrigued by features that could reduce the overall cost than the ones that deliver much broader capabilities to users.

   Manufacturers would consider a solution that requires hardware replacement and sooner delivery of 6G as that boosts their revenue. The advent of the 6G will also significantly affect the labour market. The primary requirement for the advancement of 6G lies in qualified and skilled personnel in all things related to IT, AI robotics, data analysis, etc. This implies that a certain number of unqualified positions may come to a cease.

   On the other hand, it may open up more jobs wherein advanced skills will be the essential factor. Infrastructure cost is one of the most significant investments in deploying a new generation of wireless technology. Building the required network of antennas and other requirements will be a weighty investment for telecom companies and governments. As technology advances and deployment becomes widespread, the cost can be examined over several years.

   New requirements emerge with each new generation of wireless technology. This implies that users will have to purchase new devices, such as IoT devices, tablets, etc., that support 6G networks. Though these devices may initially be priced at higher rates, they could decrease with time as production increases. 6G is expected to bring many benefits, such as lower latency, faster data speeds, and other support needed for emerging technologies. These could facilitate economic growth in various industries, thus covering the initial costs of 6G deployment.

   Post deployment of 6G networks, ongoing operating costs linked with maintaining and upgrading infrastructure will arise too. These costs will be included in the pricing of services being offered by telecommunication companies. Both private companies and institutions will require significant investments in prototyping, testing, and fundamental research. Though these costs are borne by the organizations providing the network, they could directly affect prices for users and other businesses.

   Changes in the base station:

   6G being in the initial stages of development, some refinements that could be made in base stations are explained below:

   In contrast with 5G, as 6G networks would provide for higher data rates(1TBPS), base stations need to be modified to deal with increased throughput, which may further require other advanced signal processing and antenna technologies. To support massive multiple inputs and multiple outputs, base stations may need more distributed arrays, thus improving spectral efficiency and enabling better spatial multiplexing for increased capacity. Base stations may need to integrate more advanced mm-wave antennas to support higher frequencies effectively.

   Dedicated hardware for AI processing might be incorporated at base stations to enable real-time optimization and self-configuration. 6G mobile networks introduce satellites and unmanned aerial vehicles as aerial base stations (ABS) in the 6G era. These are highly potential in enhancing the capacity and coverage of 6G networks. A significant focus would be placed on maximizing the energy efficiency of base stations to manage their operational costs. This includes making advancements in sleep modes, smart power management techniques, and power amplifier efficiency.

   Base stations may need to support network slicing to facilitate the creation of multiple virtual networks within the same physical infrastructure and provide dynamic allocation of resources. With a surge in need for security in wireless communication, 6G base stations are likely to have advanced security features to protect against cyber threats.

   The goal of 6G is to achieve ultra-low latency communication, which is crucial for applications such as autonomous vehicles, virtual reality, augmented reality, and gaming. To achieve this, base stations must minimize processing delays and optimize communication protocols. Base stations might adopt more reconfigurable architectures to adapt to changing network conditions and accommodate new applications instantly.

   Base stations may effortlessly integrate satellite and terrestrial communication capabilities. 6G base stations may adopt quantum communication techniques to provide safe and secure communication channels. These quantum encryption methods offer unprecedented security levels, thus protecting against 3rd party interception. A strong possibility of holographic antennas that provide greater efficiency and flexibility coming into existence is also implied.

   Changes in handsets:

   Handsets will have to undergo some enhancements to support the features of 6G. To support higher frequency bands such as the terahertz spectrum, handsets will need to incorporate antennas and RF front-end components capable of withstanding these higher frequencies. More power processors and graphic units will be a requirement for handsets to handle the high processing demands of the 6G network, thus enabling support for advancements such as augmented reality, real-time AI applications, and virtual reality.

   Handsets may also include specially designated AI processing units to support tasks such as predictive analytics and customized services. Handset designs may accommodate new technologies by including thinner form factors and innovative designs to maintain user comfort and usability. Higher resolution screens, advanced display technologies, higher refresh rates, and support for new display formats will be built in handsets for multimedia experiences. The main goal of 6G networks is to achieve ultra-low latency communication. To facilitate this, handsets will need to minimize processing delays and optimize communication protocols.

   6G handsets have an excellent potential for supporting multi-modal connectivity, such as effortless integration of cellular, Bluetooth, and wi-fi, thus providing users greater flexibility. Handsets will incorporate advanced security procedures such as biometric authentication methods and modern encryption technologies to ensure user privacy and prevent unauthorized access. With the increase in processing demands and data rates, a greater emphasis will be laid on improving the energy efficiency of handsets. This will be laid on the basis of advancements in power management techniques and optimization of software algorithms. Handsets will include more advanced antenna designs, such as metamaterial antennas or phased array antennas, to facilitate the use of higher frequencies in 6G networks.

   IoT impact:

   The IoT establishes a connected environment by connecting everything to the Internet, where communications, data processing, and sensing are conducted automatically without human intervention. The IoT is how devices communicate and connect with other devices with the software and process that makes communication possible. Integration of 6G will enhance the compatibility of innumerable devices across different networks and give users assurance for various tasks and projects. As per research conducted by Cisco, by 2030, up to 500 billion IoT devices will be connected to the Internet. As 6G will facilitate:

   • Full-dimensional wireless coverage
   • Merge all functionalities such as transmission, computation, and cognition
   • Be a significant enabler for future IoT networks and applications, it is expected to enhance adaptability for better IoT connectivity and service delivery.

   6G is highly potential in revolutionizing the IoT landscape by allowing more reliable, and scalable connectivity for varied services and applications. It is expected to provide faster data transmission and reception speeds with lower latency. Thus, IoT devices will be able to communicate within and outside the system more quickly, further enabling real-time response and data processing. The increased capacity of 6G networks will be able to support a much more significant number of sensors, further enabling extensive and granular data collection and ensuring accurate predictions and better insights. Facilitation of the integration of edge computing with IoT devices will be done by 6G. This could lead to developing and enhancing IoT applications across multiple industries, such as information technology, healthcare, and transportation.

   Owing to improved efficiency and capabilities, 6G will be able to support a massive deployment of IoT devices across the system. Latency reduction and bandwidth optimization can be achieved by processing data closer to the source at the network edge. This helps in more efficient usage of network resources with a faster response. 6G will ensure the incorporation of advanced security features and authentication mechanisms. This further helps in alleviating security risks such as data breaches, unauthorized access and tampering associated with IoT devices. The integration of IoT devices with 6G can accelerate the inclusion of artificial intelligence in IoT applications. With the help of faster data transmission and processing capabilities, IoT devices can leverage artificial intelligence algorithms for anomaly detection, decision-making, and real-time analytics.

   Offering high performance, 6G will be energy efficient too. This serves as an essential factor for IoT devices, as most of these are battery-operated or have limited energy resources. 6G networks can prolong the battery life of IoT devices and reduce their environmental footprint by optimizing energy consumption. Owing to lower latency rates, 6G will reduce the delay between data transmission and reception to barely some seconds. This could benefit all IoT time-bound devices. With time, we can expect more innovative IoT applications. Thus, 6G will significantly provide for future IoT networks and full-fledged coverage, integrating all functionalities such as sensing, computation, transmission, and automated control.

   AI impact:

   As 6G communication technology will use artificial intelligence with edge computing:

   • It will bring servers closer to the users from the cloud
   • The faster speed and reduced latency of 6G networks will enable AI applications to process and access data more quickly
   • Because of higher bandwidths and faster data speeds, AI systems would process and transmit larger volumes of data in real-time, thus enabling more sophisticated applications such as translation, autonomous vehicles, and augmented reality.

   Lower latency in 6G networks would allow artificial intelligence- based applications to respond more quickly to user inputs, providing a smoother experience. For instance, autonomous systems will be able to make decisions within a fraction of a second based on real-time data. Edge computing capabilities supported by 6G networks would allow artificial intelligence algorithms to run directly on devices instead of relying on centralized servers. This reduces latency and improves privacy by processing data locally, enabling more efficient usage of network resources.

   6G has the ability to provide more reliable connectivity in densely populated areas, thus expanding the reach of artificial intelligence applications. This lets AI systems gather data from a vast range of sources and make more insightful decisions. Algorithms based on artificial intelligence will be used to optimize 6G networks in real-time, dynamically adjusting parameters such as signal strength and frequency allocation and maximizing performance and efficiency. The convergence of 6G and AI will induce societal transformations extensively. It has the potential to reshape everyday life and all the operational industries.

   AI-based cybersecurity measures can be devised to detect and mitigate threats, thus ensuring the security of the network against malicious attacks. By utilizing the power of 6G networks, AI systems can traverse complex use cases, optimize results, and mitigate threats. The enhanced data processing power of 6G networks empowers artificial intelligence algorithms to tackle complex tasks more effectively, offering users unparalleled ease and efficiency. The synergy of artificial intelligence and 6G enables predictive analytics in the identification and rectification of network issues. AI-based 6G networks will allow for the sophistication of autonomous vehicles and drones, offering more reliability and operability.

   Artificial intelligence combined with 6G will:

   • Optimize infrastructure management and public services in smart cities
   • Manage traffic flow, support public safety, and monitor conditions in real-time
   • Bring a transformation in smart factories by taking advantage of real-time data analytics, enhancing productivity, implementing predictable maintenance, and adapting to changes quickly

   The predictive capabilities of AI and the bandwidth of 6G will unlock high-fidelity experiences on how users interact with digital content. Thus, with the advent of 6G technology, artificial intelligence will be bringing in a new set of applications and services. However, despite the convergence of AI and 6G offering potential advantages, organizations will have to implement strict security measures to ensure data safeguarding. Artificial intelligence techniques possess innumerable benefits, such as reduced processing delays within the systems.

   Changes in PHY(Physical) layer:

   5G majorly operates in sub- 6GHz and mm Wave frequency bands. 6G, on the other hand, will explore usage of terahertz frequencies offering a broader spectrum. Though this would enable higher data rates, it would require addressing more challenges pertaining to attenuation and signal propagation. 6G could further advance the concept of massive multiple input multiple output technology introduced by 5G. This will involve deploying larger antenna arrays with approximately thousands of antenna elements, allowing higher spatial multiplexing gains, better coverage, and improvised spectral efficiency. There are high chances of 6G introducing new waveform designs specifically optimized for THz frequencies and massive MIMO systems.

   However, these would also need to apprise issues such as Doppler effects, synchronization issues, and signal distortion. Spatial modulation could be more extensively adopted in 6G. Herein, specific antennas are activated to transmit data, thus increasing spectral utilization and energy efficiency. Beamforming techniques would further advance 6G to cope with the challenges of THz operational frequencies. It would include beam alignment, more sophisticated beam tracking, and management algorithms to establish reliable communication irrespective of channel conditions.

   For security purposes, 6G will:

   • integrate principles of quantum communication into the PHY layer to enhance security
   • involve the development of quantum key distribution (QKD) mechanisms and quantum-safe encryption schemes to provide protection to communication channels from quantum attacks
   • employ advanced error correction and channel coding techniques to mitigate the effects of higher propagation losses and increased signal impairments at THz frequencies.

   This could also lead to the deployment of new coding schemes tailored to THz characteristics. Besides, 6G PHY layer designs might prioritize energy efficiency. Smart power management techniques, energy harvesting, and power-efficient hardware designs could also be employed to facilitate energy efficiency.

   Changes in RF (Radio Frequency) layer:

   Several changes will have to be made in the RF layer to incorporate 6G. 6G will be operating at much higher frequencies in contrast with 5G, which would be offering significantly greater bandwidths and faster data transmission and reception rates. These frequencies will have to face challenges pertaining to attenuation and propagation, which need to be addressed in the RF layer design.

   6G networks are about to encompass more dynamic and intelligent radio resource management algorithms. These include sophisticated techniques for spectrum allocation, optimization, and sensing to effectively utilize resources and adapt to changing network conditions in real time. 6G networks will likely prioritize energy efficiency, keeping the need for sustainability in focus. This may be achieved by developing low-power RF transceivers, intelligent power management techniques, and energy-efficient protocols to reduce energy consumption and extend battery life for devices.

   Advanced beamforming techniques and massive multiple-input multiple-output will be integral in the RF layer of 6G. These will increase network capacity, enhance the reliability of communication links, and improve spectral efficiency by using multiple antennas for transmission and reception. Since security and privacy features will be of utmost importance in 6G networks, the RF layer may incorporate techniques such as secure channel coding, physical layer security, and encryption to safeguard data and prevent unauthorized access.

   6G will coalesce satellite communications with terrestrial networks to provide ubiquitous coverage, especially in remote areas. To achieve this, advancements in RF technologies will be necessary to support effortless handover between satellite and terrestrial networks, diminishing the effects of signal attenuation and latency effects, as well as connectivity and efficient handover between cells.

   The RF layer will have to support effortless deployments, and 6G will employ ultra-dense network deployments to increase network capacity and coverage and keep up with the increasing demand for high data rates and lower latency.

   Changes in MAC (Medium Access Control) layer:

   Due to the scarcity of spectrum bands and growing demand for spectrum resources, 6G MAC protocols will incorporate dynamic spectrum access techniques to utilize spectrum resources effectively. This indicates a possibility of involving cognitive radio capabilities that let devices access unused spectrum bands while ensuring coexistence and interference mitigation. The 6G MAC layer will incorporate enhanced privacy and security features to protect against rising vulnerabilities and threats. This will include the coalescence of secure encryption schemes, authentication, intrusion detection, and intrusion prevention mechanisms to protect user data and communication channels. To achieve sustainability goals, 6G MAC protocols will prioritize green communication principles and energy efficiency.

   This could lead to the development of energy-aware MAC protocols that minimize energy consumption in networks and wireless devices through power control, duty cycling, and sleep mode operation. 6G MAC layer protocols must support multiple access technologies such as wi-fi, IoT protocols, and multiple radio access technologies to accommodate varied device types and use cases. This could lead to the development of MAC protocols capable of effective management of resources across heterogeneous access networks and enablement of effortless mobility and connectivity for users.

   MAC layer protocols may incorporate machine learning and artificial intelligence techniques for optimization of resource allocation, interference management, and schedule, owing to the growing complexity of 6G networks and the need for adaptive resource management. This will enable dynamic adaptation to changing network conditions and traffic patterns, improving efficiency and performance.

   The MAC layer in 6G is also looked after to support applications requiring stringent latency and reliability requirements, such as industrial automation, augmented and virtual reality, and autonomous vehicles, by prioritizing ultra-reliable, low-latency communication. This will involve the development of MAC layer protocols optimized for quick access to communication channels and low-latency data transmission.

   Some downsides to 6G:

   Deploying a nationwide 6G network will require a considerable investment in developing infrastructure, which may ultimately affect the users. There are also some concerns about the potential health risks associated with exposure to higher radio frequencies used in 6G. Further in-depth research and transparent communication are crucial to fix these concerns.

   6G technology is still under development, and its final structure may or may not change. Hence, there may be unexpected delays and challenges before 6G is operational at its maximum potential, thus making it seemingly tough to predict its accurate impact. Privacy issues, the potential misuse of data, and digital divide are some of the ethical considerations that need to be addressed for the equitable deployment of 6G.

   As 6G networks will be more complex than the existing ones, advanced technologies like massive multiple input multiple output, terahertz frequencies and dynamic spectrum sharing must be incorporated. Optimization and management of these complex networks may be troublesome for network operators, service providers, and equipment vendors.

   Bridging the digital divide will require hefty and target-specific investment and policy initiatives to ensure equal access to all users, irrespective of the area. Higher frequency bands used in 6G networks are more susceptible to greater attenuation and propagation losses. This could lead to limited coverage areas and bigger challenges in providing reliable connectivity in densely packed environments.

   To sum it up, despite 5G being promising, it hasn't sufficed to meet the rapidly ever-growing wireless communication requirements. This led to envisioning 6G networks to cater to the demands of the new gen communication systems. The advent of 6G will unravel a huge milestone in the advancement of wireless communication technology, revolutionizing connectivity and allowing functioning of transformative applications across manifold industries. 6G networks are expected to deliver unparalleled levels of speed and connectivity, thus marking the dawn of a new era of immersive experiences via technological advancements. 6G can be the ultimate solution to all the bottlenecks of previous generations. However, deployment and maintenance of 6G networks will be a pretty daunting task owing to the high infrastructure expenditure involved, challenges related to technological complexities, and various other concerns discussed above. With a few uncertainties covered, the new journey towards 6G networks will let us reap the most benefits from it as they will be extremely potent in reiterating the collaboration, communication, and innovation ways, thus driving human progress in the upcoming years.

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