Data Center Networking
Article | July 5, 2023
5G small cells form the backbone of the modern wireless networks. Learn more about this technology is revolutionizing 5G deployment and enabling various use cases across industries in this article.
Contents
1 Introduction to 5G Small Cells for Modern Businesses
2 5G Small Cells: Overview
2.1 Characteristics of 5G Small Cells
2.2 How Small Cells Fit into 5G Architecture
3 Benefits of 5G Small Cells for Businesses
3.1 Improved Coverage and Capacity
3.2 Enhanced Network Performance
3.3 Lower Latency
3.4 Cost-effectiveness
4 Use Cases for 5G Small Cells
4.1 Urban Areas
4.2 Rural Areas
4.3 Indoor Environments
5 Conclusion
1 Introduction to 5G Small Cells for Modern Businesses
Small cells are low-power radio access nodes that operate in licensed and unlicensed spectrum bands and are typically deployed in areas with high demand for wireless connectivity. They are a vital component of the 5G wireless network architecture and are designed to complement traditional cell towers, providing improved coverage, network capacity, and faster data speeds. Small cells come in several types, including femtocells, picocells, and microcells, and can be deployed according to the use case.
2 5G Small Cells: Overview
2.1 Characteristics of 5G Small Cells
5G small cells are characterized by small form factors and are designed to be compact and discreet for deployment in various settings, such as urban areas, rural areas, indoor environments, and public spaces. In addition, they consume less power than traditional cell towers, making them more energy-efficient. They also operate on high-frequency bands, which enables them to provide faster data speeds and lower latency than traditional cell towers, which makes small cells essential for 5G.
The 5G small cell architecture can be deployed in dense networks, providing better coverage and capacity in areas where traditional cell towers may not be able to reach. Also, a 5G small cell antenna can be configured to provide seamless handoffs between cells, ensuring users have a consistent and uninterrupted wireless experience. These characteristics make them ideal for specific 5G use cases, which will be explored further in the article.
2.2 How Small Cells Fit into 5G Architecture
Small cells and 5G evolution are closely linked, and this technology is an ideal solution for future wireless networks. They offer greater capacity, coverage, and flexibility than traditional cell towers, allowing them to meet the demands of an increasingly connected world.
By operating on high-frequency bands and being deployed in dense networks, small cells in 5G can provide faster data speeds, lower latency, and better coverage than previous generations of wireless networks. Additionally, their small form factor and flexible deployment options allow for use cases like private 5G networks that revolutionize industries.
3 Benefits of 5G Small Cells for Businesses
5G networks will support a massive increase in connected devices, including smartphones, IoT sensors, and other devices. Small cells are critical for achieving the full potential of 5G networks and the exciting new applications and services they will enable.
3.1 Improved Coverage and Capacity
5G small cells offer improved coverage over traditional cell towers in certain situations, particularly in urban areas. Buildings and other obstacles interfere with wireless signals, so the connection quality decreases in areas with such infrastructure. By deploying small cells closer to users, the network can provide better coverage and capacity in these areas.
Small cells can also be deployed indoors, providing better coverage and capacity in buildings and other enclosed spaces. This is important due to poor wireless range, signal interference from walls, and other obstacles. By deploying small cells indoors, the network can provide better coverage and capacity in these areas, improving the overall wireless experience for users.
3.2 Enhanced Network Performance
The deployment of small cells enables network densification, which allows several devices to connect to the network simultaneously. This can help reduce network congestion and improve overall network performance, particularly in urban areas. They can also be configured to provide seamless handoffs between cells, ensuring that users have a consistent and uninterrupted wireless experience. This is important because users often move between different areas with different coverage levels and capacities, providing a streamlined experience.
3.3 Lower Latency
Small cells are designed to operate on high-frequency bands, which enables them to provide faster data speeds and lower latency than prior generations of wireless networks. This is especially important for applications that require real-time communication, such as virtual reality, autonomous vehicles, and remote surgery. By providing faster data speeds and lower latency, small cells can help enhance these applications' performance, providing a better overall user experience.
3.4 Cost-effectiveness
Small cells offer a cost-effective alternative to traditional cell towers, particularly in urban areas with high land and real estate costs. By mounting 5G small cell antennas on existing infrastructure, such as lampposts and buildings, deployment costs can be lowered. Additionally, small cells can be deployed in a modular fashion, allowing for targeted and cost-effective expansion based on the required coverage and capacity. This approach avoids large-scale and expensive deployments of new infrastructure. Moreover, small cells can be powered by low-cost, low-power sources like solar panels or batteries, reducing ongoing operational costs. Furthermore, small cells consume less power than traditional cell towers, resulting in lower energy costs.
4 Use Cases for 5G Small Cells
4.1 Urban Areas
As discussed previously, small cell radio antennas in 5G can improve networks in dense urban environments, alleviating network congestion and improving data speeds. In addition, by deploying small cells in areas with high user demand, network operators can provide targeted coverage and capacity improvements to specific areas, ensuring that users have fast and reliable connectivity.
4.2 Rural Areas
Small cells can be used to extend coverage to underserved or unserved areas by traditional cell towers. They can fill in coverage gaps, providing reliable connectivity to users in rural areas that may not have access to high-quality wireless services. This will enable use cases such as remote workforces in rural areas, smart agriculture, and distance education and training.
4.3 Indoor Environments
Traditional cell towers may not be able to provide reliable connectivity indoors due to physical barriers such as thick walls and ceilings. Small cells can provide targeted coverage and capacity to specific areas, such as conference rooms or shopping malls, where users require high-quality wireless connectivity. In addition to improving range, small cells can help alleviate network congestion and improve data speeds in high-traffic indoor environments.
5 Final Thoughts
Small cells are a crucial element in developing and implementing 5G technology. By leveraging a small form factor and high-frequency band usage, small cells facilitate the deployment of 5G networks in a more cost-effective and targeted manner than traditional cell towers. They support a wide range of use cases by providing reliable and high-quality wireless connectivity to a growing number of devices. They will continue to be a critical technology for businesses and organizations seeking to leverage the benefits of 5G technology.
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Network Management, Network Security
Article | July 17, 2023
In an increasingly digital world where every pillar of information is now online, lightning-fast connectivity, rock-solid reliability, and impenetrable security are transforming into essentials within the network industry. 5G transforms the connected ecosystem and pushes the boundaries of connectivity to lay the foundation of a faster, more secure, and sustainable future.
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Unified Communications, Network Security
Article | July 10, 2023
The year 2020 was supposed to be a breakthrough year for many technologies but, most businesses have now been forced back into building an infrastructure to transit their workforce to work remotely and ensure continuity of workflow. Nevertheless, an unprecedented set of events have pushed several industries to accelerate the adoption of technologies as they continue to work from home.
5G and Wi-Fi 6 are two tech advancements that have been turning eyes around the world since their introduction. The two wireless technologies are well on their way to revolutionize the Internet of Things as businesses move fast towards digitization and the world is excited.
Table of Contents:
- Wi-Fi 6: A Breakthrough in Wireless Technology
- 5G: For a Better Connected World
- How are Wi-Fi 6 and 5G Transforming the IoT?
- 5G and Wi-Fi 6: Rivals or Allies?
Wi-Fi 6: A Breakthrough in Wireless Technology
The next-generation Wi-Fi with boosted speed was introduced last year to meet the demand for faster internet amongst the rising internet users. But, Wi-Fi 6 is simply more than a tweak in the speed.
Technically called 802.11ax, Wi-Fi 6 is the advancement in the wireless standard doing the same basic things but with greater efficiency in the device-dense areas, and offering much greater bandwidth than its predecessor 802.11ac or Wi-Fi 5. Wi-Fi 6 promises a speed up to 9.6 Gbps up four times than that of Wi-Fi 5 (3.5Gbps). In reality, this is just a theoretical maximum that one is not expected to reach. Even still, the 9.6Gbps is higher speed and doesn’t have to go to a single device but split up across a network of devices.
A new technology in Wi-Fi 6 called the Target Wake Time (TWT) lets routers set check-in times with devices, allowing communications between the router and the devices. The TWT also reduces the time required to keep the antennas powered to search for signals, which in turn also improves battery life.
Wi-Fi 6 also comes with a new security protocol called WPA3, making it difficult to hack the device passwords by simple guesswork.
In short, Wi-Fi 6 means better speeds with optimized battery lives, and improved security.
5G: For a Better Connected World
5G is the next in line to replace 4G LTE. While Wi-Fi covers small scale internet requirements, cellular networks like 5G are here to connect everyone and everything virtually on a larger scale.
The technology is based on the Orthogonal frequency-division Multiplexing (OFDM) that reduces interference by modulating a digital signal across several channels. Ability to operate in both lower bands (like sub-6 GHz) and mmWave (24 GHz and above), 5G promises increased network capacity, low latency and multi-Gbps throughput. 5G also uses the new 5G NR air interface to optimize OFDM to deliver not just better user experience but also a wider one extending to many industries, and mission-critical service areas.
The 5G technology, in a nutshell, has brought with it ultra-high speeds, increased and scalable network capacity, and very low latency.
How are Wi-Fi 6 and 5G Transforming the IoT?
5G and Wi-Fi 6 will fill up the speed gaps that our existing networks are not able to especially, in crowded homes or congested urban areas. It's not just about the speed. The two wireless technologies will increase network capacity and improve signal strengths.
On the business front, 5G and Wi-Fi 6 are both living up to the hype they created since their introduction.
Wi-Fi 6 has emerged, as the enabler of converged IoT at the edge. It has put IT into OT applications, connected devices and processed data from devices such as IP security cameras, LED lighting, and digital signage with touch screen or voice command. Wi-Fi 6 can now be used in office buildings for intelligent building management systems, occupancy sensors, access control (smart locks), smart parking, and fire detection and evacuation.
It’s (Wi-Fi 6) built for IoT. It will connect many, many more people to mobile devices, household appliances, or public utilities, such as the power grid and traffic lights. The transfer rates with Wi-Fi 6 are expected to improve anywhere from four times to 10 times current speeds, with a lower power draw, i.e. while using less electricity.
- Tom Soderstrom, IT Chief Technology and Innovation Officer at NASA’s Jet Propulsion Laboratory (JPL)
Similarly, 5G will open doors for more devices and data. It will increase the adoption of edge computing for faster data processing close to the point of action. The hype around 5G is because of the three key attributes it comes with: enhanced mobile broadband (eMBB), ultra-reliable low-latency (uRLLC), and massive IoT device connectivity (mMTC). But there is the fourth attribute that sets it apart from its predecessor: use of a spectrum that operates at the low-end frequency range (typically 600 MHz). Called as ‘low-band 5G’, it delivers high speeds with signals that go for miles without propagation losses and ability to penetrate obstacles. The 5G operates in the new millimetre-wave bands (24 to 86 GHz) delivering more capacity to enable many low-power IoT connections.
If we were to point down the benefits, these two wireless technologies are bringing to the Internet of Things those would be:
Increased Human-Device Interactions
Increased Data and Devices
More IoT investments
Advancing to the Edge
Acceleration towards Industrial IoT
Enhanced use of IoT devices
Better VUI
5G and Wi-Fi 6: Rivals or Allies?
In February, Cisco estimated that by 2023 M2M communications will contribute to 50% or about 14.7 billion of all networked connections. Cisco’s Annual Internet Report reveals that 5G will enable new IoT applications with greater bandwidth and lower latencies and will accelerate innovations at scale. The same report estimates that 10.6% of global mobile connections in 2023 will be 5G, while Wi-Fi 6 hotspots will be 11.6% of all public Wi-Fi hotspots growing 13 times from 2020 through 2023.
Wi-Fi6 will serve as a necessary complement to 5G. A significant portion of cellular traffic is offloaded to Wi-Fi networks to prevent congestion and degraded performance of cellular networks (due to demand).
- Thomas Barnett, Director of Thought Leadership, Cisco Systems
The two technologies are here to feed different data-hungry areas with gigabit speeds.
With lower deployment costs, Wi-Fi 6 will be dominating the home and business environments where access points need to serve more users covering devices like smartphones, tablets, PCs, printers, TV sets, and streaming devices. With an unlicensed spectrum, the performance of Wi-Fi 6 depends on the number of users, that are using the network at the same time.
5G, with its longer range, will deliver mobile connections and accelerate smart city deployments and manufacturing operations. Like LTE, 5G speeds will depend upon users’ proximity to base stations and the number of people using that network.
The performance of the two depends largely on the area where they are being deployed. For instance, Wi-Fi can very well handle machine-to-machine communications in a managed manufacturing unit, whereas 5G can enhance campus-wide manufacturing operations efficiently. Businesses will have a decision to make which among the two wireless networks fulfils their data appetite.
In conclusion, the two wireless technologies continue to develop in parallel and causing the next big wave in the Internet of Things.
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Article | April 20, 2020
Coronavirus (COVID-19) has been relentlessly spreading across the world. Countless events, both international and domestic, big and small, have been either postponed or canceled due to the ongoing pandemic. This was supposed to be the year the 5G network rollout would make the technology mainstream and widely available. But the much-anticipated rollout of the lightning-quick 5G network may now be in the slow lane. Because of the increasing spread of the disease in many European countries, various 5G network spectrum regulators have postponed the long-awaited auction of the 5G spectrum. These auctions were crucial for network providers to launch or expand the already existing 5G network systems.
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