Posts Tagged ‘5g’

The Truth About 5G Safety

Written by Brooks Canavesi on . Posted in Technology trends

All around the world, carriers are rolling out the latest generation of cellular network technology, 5G, which promises much higher data rates, lower latency, and increased capacity. In the Ericsson Mobility Report, the multinational networking and telecommunications company predicts that 5G networks could carry 35 percent of mobile data traffic globally by 2024.

However, not everyone is looking forward to the benefits of 5G networks. In fact, some worry that the latest generation of cellular network technology could have a profoundly negative effect on the health of all people who become exposed to it. Let’s explore the reasoning behind these fears to find the truth about 5G safety.

Meet 5G

A decade has passed since the first commercial deployment of the fourth generation of broadband cellular network technology, better known as 4G. Since then, the number of connected devices has exploded, and the Internet of Things has matured beyond buzzword status into a fact of life in developed and developing countries alike.

The current broadband cellular network technology is unable to satisfy the growing need for high-performance, low-latency cellular connections. 5G promises to enable billions of new connections with at least a tenfold improvement in network performance. It also promises network latency that doesn’t exceed a couple of milliseconds and a high-capacity, high-reliability architecture comprising of many small cells.

“5G will enable blossoming technologies that rely on connectivity to the internet to go widespread, from connected self-driving cars to smart plugs, lights, cameras, toothbrushes, thermostats, healthcare monitoring devices and more,” writes Ethan Siegel, a senior Forbes contributor and the author of science blog Starts With A Bang. “The Internet of Things is coming, and 5G is the technology that will take it mainstream.”

Is the Cost of 5G Too High?

To deliver on its promises, 5G technology uses both the existing LTE frequency range (600 MHz to 6 GHz) and millimeter wave bands (24–86 GHz). Today, millimeter-wave bands, also called mmWave, are used mostly for satellite and point-to-point radio links. Some people are worried that prolonged exposure to higher doses of millimeter-wave bands could have negative biological effects because radiofrequency energy at these frequencies is absorbed superficially by the body, mostly by the skin.

There were even protests earlier this year in Wales and Switzerland, with thousands of protestors demonstrating against the rollout of the new technology. When opponents of 5G are asked why they believe the technology could be harmful, they often refer to the World Health Organization (WHO) and its classification of all radiofrequency radiation as possibly carcinogenic.

More recently, some 5G critics have been mentioning a toxicology report released in 2018 by the US Department of Health, which found that male rats exposed to high doses of radiofrequency radiation developed a type of cancerous tumors in the heart.

To add fuel to the fire, there are researchers like Joel M. Moskowitz, who is known for publicly voicing his concerns about the possible health risk of 5G. Moskowitz works on public health issues that include cell phone risk, tobacco control, and alcohol abuse at the faculty of the School of Public Health at the University of California, Berkeley, published an influential article in Scientific American, titled “We Have No Reason to Believe 5G Is Safe.”

Does this mean that 5G is really dangerous and that there is a valid reason for concern? To properly answer this important question, it’s necessary to start with a brief explanation of the science behind cellular communication.  

Understanding Radiofrequency Radiation

At the heart of the fears surrounding the rollout of the latest generation of cellular network technology is something called radiofrequency radiation (RFR), which is the radiation (the emission or transmission of energy in the form of waves or particles through space or through a material medium) produced by the transfer of energy by radio waves.

Even though RFR sounds scary and is often associated with nuclear radiation, the two types of radiation differ in one very important aspect: RFR is non-ionizing, just like all lower-energy radiation, which includes optical (visible) and infrared (heat) radiation.

Low-energy radiation is also called non-ionizing radiation because it doesn’t have enough energy to detach electrons from atoms or molecules and thus cause damage at the cellular level to biological organisms.

On the other hand, the radiation from x-rays is probably the most known form of ionizing radiation, and there’s a very good reason why doctors always try to minimize exposure to it as much as possible with lead shields and other radiation protection solutions.

No Reason to Fear

Even though millimeter-wave bands have a much higher frequency than LTE bands, they are still very much in the non-ionizing part of the electromagnetic spectrum. Because RFR has such a low power, even prolonged exposure to it is nothing compared with the exposure to sunlight.

“To put it in context, the weakest visible light is more than 17,000 times more energetic than the highest-energy 5G photon possible. Were they consistent, anti-5G activists should be orders of magnitude more concerned about light bulbs than cellular phones. The fact that they aren’t is indicative of a gross misunderstanding,” writes David Robert Grimes, an Irish physicist, cancer researcher, and science writer.  

What’s more, the power of 5G signals sharply decreases with distance. What would be classified as a high radiation dose when standing just a few inches away from the sour goes down by a factor of 10,000 about 33 feet from it. It’s estimated that a portable radio or boombox produces far more radiation of similar frequencies when held close to the body as one would receive from a 5G device carried in a pocket.

“The maximum radio frequency level that someone in the community could be exposed to from 5G (or any other signals in general community areas) is so small that no temperature rise has been observed to date,” says Professor Rodney Croft, an adviser to the International Commission on Non-Ionizing Radiation Protection (ICNIRP). In other words, 5G and earlier mobile technologies don’t produce any harmful heating effects.

According to one scientist who worked on the report that found that male rats exposed to high doses of radiofrequency radiation developed a type of cancerous tumors in the heart, “exposures used in the studies cannot be compared directly to the exposure that humans experience when using a cell phone,” and that goes even for heavy users. In fact, the same study found that rats exposed to the radiation lived longer than those in the control group.

The fact that the WHO classified all radiofrequency radiation (of which mobile signals are a part) as possibly carcinogenic doesn’t sound too scary when you learn that this category is used for agents, mixtures, and exposure circumstances for which there is limited evidence of carcinogenicity in humans, such as pickles. Alcoholic drinks and processed meat are in a higher category because the evidence is stronger.

“Using the term radiation is misleading because people think of nuclear weapons—they think of ionizing radiation that absolutely can cause damage. It can kill cells. It can cause DNA mutations,” says Dr. Steve Novella, an assistant professor of neurology at Yale and the editor of Science-Based Medicine. “There’s no known mechanism for most forms of non-ionizing radiation to even have a biological effect,” he says.

The Bigger Picture

Instead of studying the potential negative impact of individual 5G devices, it might be more useful to take a step back and look at the effect mobile technology has had on people since the very beginning. Between 1992 and 2008, cell-phone usage has grown from virtually zero to 100 percent, but there has been no indication of the increase of cell-phone usage resulting in more cases of cancer.

Numerous studies have confirmed this, many of which focused on RF workers, who install the wireless communication towers that provide the necessary infrastructure for 5G and are exposed to very high doses of RFR on a daily basis.

A good example is the 13-country INTERPHONE study, which unequivocally concluded that there was no causal relationship between phone use and incidences of common brain tumors such as glioblastoma and meningioma after to measuring the impact of cell phone usage on the human body for decades in 13 countries. There are also several long-term studies that studied radar workers, and they all concluded that the exceptional levels of RFR to which they are subjected to do not show a hint of increased cancer incidence.  

All these and many other studies paint a clear picture: no adverse health effects have been established as being caused by mobile phone use to this date, and there is no scientifically valid reason to believe that the rollout of 5G would change that.

Top 3 Emerging Technologies to Follow in 2020

Written by Brooks Canavesi on . Posted in Technology trends

The 4th industrial revolution is in full swing, and several emerging technologies are expected to profoundly impact nearly every industry in the coming year. To remain competitive, organizations must keep ahead of them, anticipating their arrival and understanding their impact to make good business decisions. Based loosely on the latest Gartner’s Hype Cycle for Emerging Technologies report, this article describes the top 3 emerging technologies to follow in 2020.

1. 5G Connectivity

The fifth generation of cellular network technology is designed to support 1,000-fold gains in capacity to connect at least 100 billion devices and provide extremely low latency and much higher data rates than 4G.

Already, the largest telecommunication companies in the world are rolling out 5G in countries like the United States, South Korea, and China. In 2024, 5G networks are expected to cover up to 65 percent of the world’s population, enabling the Internet of Things to grow at an unprecedented rate and creating the opportunity for organizations to take advantage of faster internet speed and lower latency.

The first 5G-enabled smartphones have already been released, and virtually every smartphone manufacturer that matters will have at least a few models on sale in 2020.

2. Hyper Automation

In recent years, organizations across all sectors have been using a blend of artificial intelligence, machine learning, and automation tools to automate critical processes, improve efficiency, and reduce their operation expenses.

In 2020, automation is expected to reach a whole new level and include even processes that currently have been automated only partially. The new level of automation is referred to as hyper automation, and it incorporates smart and rapid automation driven by advanced analytics and machine learning.

Wipro, an Indian multinational corporation that provides information technology, consulting, and business process services, is at the forefront of hyper automation, offering a comprehensive end-to-end platform that has been designed and developed for new age telecom services.

3. Voice User Interfaces (VUI)

Voice user interfaces rely on speech recognition to understand voice commands and make spoken human interaction with computers possible. They are expected to replace graphical user interfaces as the main form of user interface that allows users to interact with electronic devices.

In the past, voice control wasn’t possible because electronic devices lacked the necessary processing power to understand voice commands in real time. However, modern CPUs are capable of running advanced language processing algorithms that leverage machine learning and artificial intelligence to accurately understand tone, puns, and even sarcasm.

The proliferation of voice user interfaces is fueled by the growing popularity of smart devices and the need to control them without a costly touchscreen on an external input device.  

Conclusion

From 5G connectivity to hyper automation to voice user interfaces, the year 2020 will see the arrival of several emerging technologies, all of which are expected to profoundly impact all forward-thinking organizations and create numerous growth opportunities. Those who manage to stay ahead of them can expect to enjoy a competitive advantage in the near future.

The Future is 5G

Written by Brooks Canavesi on . Posted in IoT, Mobile App Development, Technology trends

The very first mobile telephone call was made in 1973 by a senior engineer working for Motorola. A lot has changed since then, and we now use mobile phones for a lot more than making phones. In fact, mobile phones no longer even have a monopoly on mobile communication.

Today, we rely on a number of different cellular- and internet-connected devices (Internet of Things – IoT) to stay productive, and we’re rapidly moving toward a connected future where nearly every electronic device wirelessly sends and receives information to offer various smart features / insights.

As our needs and personal electronic devices change, the infrastructure we rely on needs to change as well. A new generation of cellular technology is introduced to the world approximately every 10 years, with the current generation, 4G, having been first commercially deployed in 2009. The time is right for the next generation of cellular technology to come and replace 4G, and we already know what it will offer.

BLUF:

1.    Horsepower – How does 10Gbps – 20Gbps sound? That is 100x faster than LTE and 10x faster than the fastest home internet connection today from a fiber provider like Verizon FiOS. Conservative estimates show expected latency to be 1/4th of LTE at 5ms from 20ms.

2.    No Cables Required – Cable companies are in trouble and will be scrambling to have a cellular presence, which can be seen with Comcast Xfinity Mobile. If you live in a major metropolitan market and are building a new home in 2019+, forget about installing coax cable.

3.    Telco Data Dwarfs Google’s – If a majority of phone, home entertainment, and IoT device internet access is funneled through 5G networks, the wireless providers of 5G will have more data access than any single technology vendor such as Facebook, Google or Apple.

4.    2020 – target for most major markets, rural areas should not hold their breath as the infrastructure priorities will continue to be major metro regions initially.

What Is 5G?

The chances are that you’ve already heard of 5G. Major carriers including Verizon, AT&T, and Sprint are testing 5G in cities around the country, and chipmakers like Qualcomm and Intel are working hard developing 5G hardware to bring the fifth generation of cellular networking to consumers worldwide.

But despite all the buzz around 5G, there’s actually no official “5G” yet. Instead, there are several definitions of 5G, each of which includes slightly different specifications.

Arguably the most common definition of 5G is the 3GPP Release 15. 3GPP is the 3rd Generation Partnership Project, a collaboration between groups of telecommunications standards association. Apart from the 3GPP Release 15, there’s also the more rigorous ITU IMT-2020 definition from the International Telecommunication Union, a specialized agency of the United Nations that is responsible for issues that concern information and communication technologies.

“If anyone tells you they know the details of what 5G will deliver, walk the other way,” noted former FCC chairman Tom Wheeler. “Our proposal is the final piece in the spectrum trifecta of low-band, mid-band and high-band airwaves that will open up unprecedented amounts of spectrum, speed the rollout of new-generation wireless networks and redefine network connectivity for years to come. I’m confident these actions will lead to a cornucopia of unanticipated innovative uses and generate 10s of billions of dollars in economic activity.”

Even though hardware manufacturers, regulatory bodies, and governments have yet to paint a clear picture of what 5G is, we already have a pretty clear idea about what some of its most important components will be. But before we take a closer look at them, it’s helpful to first walk through the evolution of cellular technology and consider how each impacted the mobile landscape.

How We Got Here?

1G

The first generation of mobile networks was introduced in the 1980s and allowed for wireless voice calls. This was the time of the Motorola DynaTAC series of cellular telephones, which took around 10 hours to charge, lasted only for 30 minutes of talk, and featured a tiny LED display that consumed as much battery power as entire smartphones do today. During the reign of 1G, the only people that could afford mobile phones were one-percenters as the Motorola DynaTAC, and many other phones, cost thousands of dollars.

2G

With the introduction of 2G, mobile networks shifted from fully analog systems to digital ones. 2G networks were commercially launched on the GSM standard in 1991 and offered encryption, much higher signal penetration, and data services for mobile, including SMS and MMS. Cellular data was enabled by GPRS, which offers a theoretical maximum transfer speed of 50 Kbps, and EDGE, which offers a theoretical maximum transfer speed of 1 Mbps.

3G

The third generation of wireless mobile telecommunications technology offered even faster data rate than 2G, which allowed it to find application in wireless voice telephony, mobile Internet access, fixed wireless Internet access, video calls, and mobile TV. It was based on the IMT-2000 standards and first made available in Japan in 1998. By June 2007, which is when the first iPhone was released, the 200 millionth 3G subscriber had been connected to the network.

4G

The requirements for the 4G standard were specified by the International Telecommunications Union-Radio communications sector (ITU-R) in March 2008, and it offered maximum data transfer speeds of 1 Gbps for low mobility communication, such as pedestrians and stationary users. However, most mobile users hadn’t been able to enjoy truly fast data transfer speeds until the arrival of 3GPP Long Term Evolution (LTE) technology and the launch of LTE services by carriers many years later. Even today, there are entire regions where 4G coverage is non-existent, and it’s highly likely that the rollout of 5G will follow a similar pattern.

Features of 5G Networks

The members of ITU have agreed on 5G performance requirements for 5G, calling for a minimum of 20 Gbps downlink and 10 Gbps uplink per mobile base stations. “The IMT-2020 standard is set to be the global communication network for the coming decades and is on track to be in place by 2020. The next step is to agree on what will be the detailed specifications for IMT-2020, a standard that will underpin the next generations of mobile broadband and IoT connectivity,” said François Rancy, Director of ITU’s Radiocommunication Bureau. ITU’s draft report also specifies extremely low latency of 5 ms, which is a significant improvement compared to 4G LTE’s 20 ms. High data transfers speeds and low latency are essential not only for mobile content consumption but also for emerging applications such as driverless cars. Beyond these foundational improvements, 5G also includes a suite of new technologies, including small cells, millimeter waves, massive MIMO, and beamforming, just to name those that are most likely to make it to consumers.

Small Cells

5G relies on high frequencies with low wavelengths that have difficulty penetrating solid objects. To ensure strong signal in densely populated areas, carriers will deploy many portable miniature base stations that require minimal power to operate to form a dense network that acts as a relay team. “This radically different network structure should provide more targeted and efficient use of spectrum. Having more stations means the frequencies that one station uses to connect with devices in one area can be reused by another station in a different area to serve another customer. There is a problem, though—the sheer number of small cells required to build a 5G network may make it hard to set up in rural areas,” explains IEEE Spectrum.

Millimeter Waves

If you’ve ever tried to set up a WiFi network in a large apartment building, you probably know how crammed the WiFi frequency spectrum is. The situation is similarly grim in the radio frequency spectrum, which is why 5G is experimenting with broadcasting on millimeter waves. Millimeter waves are broadcast at frequencies between 30 and 300 gigahertz, allowing for massive amounts of data to be transmitted without any interference issues. But millimeter waves have one huge drawback: they can’t easily travel through obstacles. That’s why they’re a good fit for massive MIMO.

Massive MIMO

Base stations today support only up to eight transmitters and four receivers. 5G cell towers of the future will support about a hundred ports, increasing the capacity of mobile networks by a factor of 22 or greater. The name of this technology is massive MIMO, and it’s the next evolutionary step from MIMO (multiple-input and multiple-output), a method for multiplying the capacity of a radio link using multiple transmit and receive antennas to exploit multipath propagation.

Beamforming

According to IEEE Spectrum, “Beamforming can help massive MIMO arrays make more efficient use of the spectrum around them.” This technology can be found in today’s high-end Wi-Fi routers, and it identifies the most efficient data-delivery route to a particular user, allowing engineers to achieve the high throughput and low latency required for 5G even when there are obstacles in the way.

When is 5G coming?

5G technology debuted at the Pyeongchang Winter Olympics, where it was used by Samsung and Intel to stream live VR coverage of sporting events. As exciting as such early demonstration of the next-gen mobile technology may be, regular mobile users will have to wait at least a few more years before they’ll be able to enjoy 5G connectivity. Intel, Qualcomm, and Samsung have all announced chipsets with 5G support, but carriers will set the pace of 5G adoption. Densely populated metropolitan areas will be covered first, while rural places may have to get by with 4G or even 3G for several more years.

Conclusion

“These next-generation networks and standards will need to solve a more complex challenge of combining communications and computing together. With 5G, we’ll see computing capabilities getting fused with communications everywhere, so trillions of things like wearable devices don’t have to worry about computing power because network can do any processing needed,” Keddy told Quartz in an interview ahead of the 2017 Mobile World Congress. The next-generation mobile technology is taking shape, promising to support billions of connected devices. From smart cities to driverless cars to augmented and virtual reality to the internet of things, 5G use cases are numerous and its impact on the world as we know it will be profound. Author’s note: This is not a sponsored post. This article expresses my own opinions not those of my company. I am not, nor is my company, receiving compensation for it.