Have you ever wondered what makes 5G so unique relative to the other “G’s?” The answer, in a word, is latency. And even if you don’t know what that is yet, it makes a big difference in the way you use your phone, whether that’s hailing a rideshare like Uber, unlocking a scooter rental, or streaming a favorite show or movie.
Here’s why 5G is fundamentally different from all the other G’s, how critical cellular networking elements make it work, and all you need to know about the role that licensed spectrum plays in making it all a reality.
Defining the G’s. G stands for generation, and every cellular-service level represents a significant step up over the last. First, there was 1G, which provided voice-only services over an analog network, and the service was fraught with dropped calls and poor security. Next up, 2G brought the advent of a digital network, and with it significant improvements in security, quality, and something we pretty much all use daily today – text messaging. Then came 3G, which represented another technology leapfrog that saw mobile data support for web browsing and video calls (and Apple’s launch of the iconic iPhone). Today, 4G is the standard we enjoy. It brought improved throughput and performance and helped birth some of the disruptive services previously mentioned.
So, what makes 5G anything more than just faster? The answer is improved latency.
Latency is the time it takes for a packet of data to travel from a sender to a receiver over a network: The lower the latency, the more responsive an application, especially if it is video intensive. Measured in milliseconds (ms), today’s 4G networks ring in at around 50ms, compared to an expected sub-5ms latency for 5G. The latter equates to nearly real-time responsiveness and is so fast it may even replace your home internet. No wonder carriers globally are eager to deploy 5G-based networks for both consumer and business applications.
The Parts That Make It Work. Core network components serve as the central part of a cellular network. They knit together mobile, fixed, and converged connectivity to ensure a more consistent user experience. The switch to 5G also brings the use of more industry-standard hardware and open-source software. Companies that deliver server, storage, and virtualization platforms such as Dell EMC, Hewlett Packard Enterprise, and VMware have made significant inroads into the telecommunications space, which has brought disruption from a cost and deployment perspective.
Some of the more recent capabilities that have come to core networking include machine learning, artificial intelligence (AI), and software-defined networking (SDN) tools. There is a degree of whitewashing with some, if not all, of these platforms, but the benefits are real. Those include faster deployment, self-healing for improved uptime, and network slicing to guarantee new service quality and new monetization opportunities for carriers and service providers.
Radio access network (RAN) components, on the other hand, play an essential role in how your smartphone or mobile device communicates across a cellular network. These include base stations, antenna arrays, and small cell platforms. Base stations are fixed points of communication within a cellular network designed to cover a specific geographic area. Based on the need for radio coverage, they can take the form of:
Licensed Spectrum. The best way to view licensed spectrum is in three buckets: The low, mid, and high bands.
For 5G, the low band provides comprehensive coverage, but only a modest improvement over 4G LTE. T-Mobile has been keenly focused on building out its low-band spectrum assets to offer the most expansive 5G coverage area, and it is an intelligent move to bring new 5G subscribers on board rapidly. The mid band balances 5G coverage with exceptional performance. It is no wonder that the recent Federal Communications Commission C-Band auction was a record-breaker in raising roughly $82B, with Verizon and AT&T spending billions of dollars to fill gaps in their respective spectrum portfolios. Finally, high band, or mmWave, provides the best 5G performance but the worst coverage. Reception is thwarted through buildings and trees, requiring many small towers to bolster signal strength. Verizon has prioritized its high band 5G buildout (branded Ultra-Wideband). Still, the challenge is that subscriber reach is limited, and service is available in just a handful of major metropolitan areas. That will improve over time, but it will not be a fast process.
Still Seeking the Killer App. The hype cycle for 5G may be at its apex, but don’t be dismayed if it feels long in coming. The reality is that 5G is not a light switch – it’s a slow dawn. New infrastructure and unlicensed spectrum, especially in the high band mmWave, will combine to deliver a fantastic 5G subscriber experience. New service offerings for both consumers and enterprises will rival 4G, thanks to the dramatic improvements in both throughput and latency. Ridesharing was the “poster child” disruptive use case in a 4G world. It will be exciting to see what unfolds in a 5G world.
Here’s why 5G is fundamentally different from all the other G’s, how critical cellular networking elements make it work, and all you need to know about the role that licensed spectrum plays in making it all a reality.
Defining the G’s. G stands for generation, and every cellular-service level represents a significant step up over the last. First, there was 1G, which provided voice-only services over an analog network, and the service was fraught with dropped calls and poor security. Next up, 2G brought the advent of a digital network, and with it significant improvements in security, quality, and something we pretty much all use daily today – text messaging. Then came 3G, which represented another technology leapfrog that saw mobile data support for web browsing and video calls (and Apple’s launch of the iconic iPhone). Today, 4G is the standard we enjoy. It brought improved throughput and performance and helped birth some of the disruptive services previously mentioned.
So, what makes 5G anything more than just faster? The answer is improved latency.
Latency is the time it takes for a packet of data to travel from a sender to a receiver over a network: The lower the latency, the more responsive an application, especially if it is video intensive. Measured in milliseconds (ms), today’s 4G networks ring in at around 50ms, compared to an expected sub-5ms latency for 5G. The latter equates to nearly real-time responsiveness and is so fast it may even replace your home internet. No wonder carriers globally are eager to deploy 5G-based networks for both consumer and business applications.
The Parts That Make It Work. Core network components serve as the central part of a cellular network. They knit together mobile, fixed, and converged connectivity to ensure a more consistent user experience. The switch to 5G also brings the use of more industry-standard hardware and open-source software. Companies that deliver server, storage, and virtualization platforms such as Dell EMC, Hewlett Packard Enterprise, and VMware have made significant inroads into the telecommunications space, which has brought disruption from a cost and deployment perspective.
Some of the more recent capabilities that have come to core networking include machine learning, artificial intelligence (AI), and software-defined networking (SDN) tools. There is a degree of whitewashing with some, if not all, of these platforms, but the benefits are real. Those include faster deployment, self-healing for improved uptime, and network slicing to guarantee new service quality and new monetization opportunities for carriers and service providers.
Radio access network (RAN) components, on the other hand, play an essential role in how your smartphone or mobile device communicates across a cellular network. These include base stations, antenna arrays, and small cell platforms. Base stations are fixed points of communication within a cellular network designed to cover a specific geographic area. Based on the need for radio coverage, they can take the form of:
- Macrocells that cover a wide area and are typically found on towers
- Microcells that are used for densification of coverage in highly populated areas that can be found mounted to streetlight poles and traffic signals
- Picocells that boost coverage within buildings.
Licensed Spectrum. The best way to view licensed spectrum is in three buckets: The low, mid, and high bands.
For 5G, the low band provides comprehensive coverage, but only a modest improvement over 4G LTE. T-Mobile has been keenly focused on building out its low-band spectrum assets to offer the most expansive 5G coverage area, and it is an intelligent move to bring new 5G subscribers on board rapidly. The mid band balances 5G coverage with exceptional performance. It is no wonder that the recent Federal Communications Commission C-Band auction was a record-breaker in raising roughly $82B, with Verizon and AT&T spending billions of dollars to fill gaps in their respective spectrum portfolios. Finally, high band, or mmWave, provides the best 5G performance but the worst coverage. Reception is thwarted through buildings and trees, requiring many small towers to bolster signal strength. Verizon has prioritized its high band 5G buildout (branded Ultra-Wideband). Still, the challenge is that subscriber reach is limited, and service is available in just a handful of major metropolitan areas. That will improve over time, but it will not be a fast process.
Still Seeking the Killer App. The hype cycle for 5G may be at its apex, but don’t be dismayed if it feels long in coming. The reality is that 5G is not a light switch – it’s a slow dawn. New infrastructure and unlicensed spectrum, especially in the high band mmWave, will combine to deliver a fantastic 5G subscriber experience. New service offerings for both consumers and enterprises will rival 4G, thanks to the dramatic improvements in both throughput and latency. Ridesharing was the “poster child” disruptive use case in a 4G world. It will be exciting to see what unfolds in a 5G world.
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