Tag Archive for mmWave

| June 19, 2020
Comments Off on 5G in the D

5G in the D

5G in the DDuring the COVID-19 lockdowns work from home saw a 34% growth. Gartner reports that in the post-COVID “new normal” (whenever that is) era 74% of businesses will move some of their previously on-site workforce to permanently remote positions. These signals problems for many Detroiters who live in one of America’s worst connected areas.

Verizon 5gVerizon may be one part of Detroit moving forward in the “new normal.” FireceWirless is reporting that Verizon (VZ) is now offering its fixed wireless access (FWA) 5G Home Internet service in the D. The telco will offer the 5G Ultra-Wideband Network in the following areas: Detroit, Dearborn, Livonia, and Troy.

Detroit
Dearborn
Livonia
Troy

The Detroit 5G Home service will use millimeter wave (mmWave) spectrum and is expected to deliver speeds of about 300 Mbps. There are several factors that affect the speed of 5G networks. Notably, the more people that are connected to a network, the slower speeds will be. Not only that, but your distance to a 5G node may impact speeds too. It also uses the same network the operator is building for mobile 5G which means the FWA product is dependent on mobile 5G being available in your area.  

5G fixed wireless access

Verizon is working on higher-powered customer premises equipment for 5G Home that’s expected to expand the coverage area supported by the fixed wireless service. But the improved CPE is not part of the initial 5G Home rollout in Motown.

5G small cell site

Detroiters will get a new “enhanced” form of the product which uses industry standard 5G-NR transmission standard that, among others things, supports a customer self-install model (cost savings for VZ). Detroiters signing up for 5G Home will get the new router. The router supports the Wi-Fi 6 standard, promising peak speeds up to 1 Gbps and allowing multiple devices to run at the same time. It also features Amazon Alexa built-in, so customers can control their smart home devices and ask questions, hands-free.

5G Home service perks

The no-contract 5G Home service starts at $50 per month for Verizon customers and $70 per month for everybody else. The operator is sweetening the deal with an offer of no cost content options to get customers to sign up. Among the perks being used to entice consumers to 5G Home, Verizon is offering:

  • One month of YouTube TV,
  •  One year of Disney+
  • Three months of Google Stadia (Google’s new cloud gaming service).

New customers can also get a free Stream TV device. The device is an Android TV-based, 4K-capable streaming product from Verizon. The device is also integrated with the Google Assistant platform and Chromecast “built-in,” which enables users to cast video from the smartphone to the TV screen. The Stream TV device gets subscribers access to a library of OTT channels, apps, and entertainment, including Netflix and Amazon Prime.

rb-

Verizon has said it plans to expand 5G Home Internet to have coverage for 30 million households. Verizon predicts that by 2035, 5G will enable more than $12 trillion in global economic revenue, and support 22 million jobs worldwide driven by the digitalization of industries such as transportation, agriculture, and manufacturing.

Not everyone is convinced that these new attempts at delivering fixed wireless broadband will be a success. Lynnette Luna, principal analyst with GlobalData, told FierceWireless that Verizon needs to provide some clarity on its strategy. “They don’t want to deploy it in places with a lot of broadband competition so they look for markets where they have an advantage but I don’t understand their formula.” 

However, she added that she thinks it’s smart for Verizon to bundle the service with other things. In particular, the demo access to Google Stadia because it showcases one of 5G’s key use cases — cloud gaming.

Stay safe out there!

Related article

 

Ralph Bach has been in IT long enough to know better and has blogged from his Bach Seat about IT, careers, and anything else that catches his attention since 2005. You can follow him on LinkedInFacebook, and Twitter. Email the Bach Seat here.

Category: Uncategorized | Tags: , , , , , , , , , , , , , ,
| June 7, 2019
Comments Off on What is 5G ?

What is 5G ?

What is 5G ?Updated 07/16/2019 – Qualcomm released the Snapdragon 855 Plus. It features a Kryo 486 CPU Prime core with a clock speed of 2.96 GHz and a 15% faster Adreno 640 GPU. Qualcomm claimed in a presser, the 855 Plus would deliver better coverage and all-day battery life in 5G devices.

AT&T (T), Verizon (VZ), Sprint (S), and other carriers are hyping 5G. But what exactly is 5G? If you believe the hype, it is the greatest thing since sliced bread. 5G will improve our homes, make our cities safer, our machines smarter, our cars driverless, our entertainment mobile and our phones faster. So what is the tech behind the hype?

When 5G really gets here will bring three improvements to current wireless: greater speed, lower latency, and more connections.  The real advantages of 5G will come in massive capacity and lower latency. The standards bodies involved are aiming at 20Gbps speeds and 1ms latency.

Work on 5G started 10-15 years before anything went commercial. Marcus Weldon, CTO, and president of Nokia Bell Labs told FierceWireless. Finally, in 2017, the 3rd Generation Partnership Project, the standards body that writes the rules for wireless connectivity, agreed on the first specification for 5G. The Non-Standalone Specification of 5G New Radio standard covers 600 and 700 MHz bands and the 50 GHz millimeter-wave end of the spectrum. But, as followers of the Bach Seat know, a standard doesn’t mean that it will work the same, or what applications it will enable.

The G in this 5G means it's a generation of wireless technologyThe G in this 5G means it’s a generation of wireless technology. PC Magazine says, most wireless generations have technically been defined by their data transmission speeds, each has also been marked by a break in encoding methods, or “air interfaces,” that make it incompatible with the previous generation. The earlier G’s were:

  • 1G was analog cellular.
  • 2G technologies, such as CDMA, GSM, and TDMA, were launched in 1991 the first generation of digital cellular technologies without much concern for data transmission or the mobile Web.
  • 3G technologies, such as EVDO, HSPA, and UMTS, brought speeds from 200kbps to a few megabits per second. It focused on applications in voice telephony, mobile Internet, video calls, and mobile TV.
  • 4G technologies, such as WiMAX and LTE, were the next incompatible leap forward, and they are now scaling up to hundreds of megabits and even gigabit-level speeds. 4G was designed to better support IP telephony, video conferencing, and cloud computing, as well as video streaming and online gaming.

The actual 5G radio system, known as 5G-NR, isn’t compatible with 4G. But for the foreseeable future, all US 5G devices will need 4G to set up 5G connections where it’s available. That’s technically known as a non-standalone,” or NSA, network. Later 5G networks will become “standalone,” or SA, not requiring 4G coverage to work.

Like other cellular networks, 5G networks use a system of cell sites that divide their territory into sectors and send encoded data through radio waves according to PCMag. Each cell site requires a network backbone connection, whether through a wired or wireless backhaul connection. 5G networks use a type of encoding called OFDM.

5G is designed to carry higher speeds by using much larger channels than 4G. While most 4G channels are 20MHz, bonded together into up to 160MHz at a time, 5G channels can be up to 100MHz, with Verizon using as much as 800MHz at a time. That’s a much broader highway, but it also requires larger, clear blocks of airwaves than were available for 4G. PCMag cites Qualcomm (QCOM) claims that 5G will be able to boost capacity by four times over current systems by leveraging wider bandwidths and advanced antenna technologies.

5G primarily runs in two kinds of airwaves: below and above 6GHz. Low-frequency 5G networks, which use existing cellular and Wi-Fi bands, take advantage of more flexible encoding and bigger channel sizes to achieve speeds 25 to 50 percent better than LTE, according to a presentation by T-Mobile (TMUS) exec Karri Kuoppamaki.

Those networks can cover the same distances as existing cellular networks and generally won’t need more cell sites.  Rural networks will likely be stuck with low-band 5G, because low-frequency bands have a great range from cell towers.

To get super-high, multi-gigabit speeds, carriers are turning to newer, much higher frequencies, known as millimeter wave (mmWave). In the existing cellular bands, only relatively narrow channels are available because that spectrum is so busy and heavily used. But up at 28GHz and 39GHz, there are big, broad swathes of spectrum available to create big channels for very high speeds.

The 28GHz and 39GHz bands have previously only been used for backhaul. But they haven’t been used for consumer devices before, because the handheld processing power and miniaturized antennas weren’t available. Millimeter wave signals also drop off faster with distance than lower-frequencies, and the massive amount of data they transfer will need more connections to landline internet. So cellular providers will have to use many smaller, lower-power base stations rather than fewer, more powerful macrocells to offer the multi-gigabit speeds that millimeter wave networks promise.

There’s a third set of 5G airwaves being used overseas. These frequencies, ranging from 3.5GHz to 7GHz. These are slightly above current cellular bands but have quantities of the spectrum (speed) that approaches mmWave. The US is falling behind other countries in the mid-band spectrum because over here, it’s being used for satellite communications and the Navy.

Bell Labs’ Weldon, described his idea of a true 5G network for FierceWireless;

you need a low band that gives you nationwide coverage—higher efficiency on it; a mid-band for high-capacity, relatively locally; and millimeter-wave for super high-capacity, extremely locally, and if you blend all those together, you’ve got a network that really is significant.

Some believe that mmWave 5G will not work. T-Mobile CTO Neville Ray wrote that millimeter-wave won’t be able to deliver on the promise of 5G because it doesn’t travel far. Jeffrey Moore, principal analyst at Wave7 Research told FierceWireless. “…there are definitely some concerns about the economics of 5G.”

rb-

5G is an investment for the next decade. It is unlikely that the next big application will drop in 5G until 2021 or 2022. It is likely that a true 5G iPhone won’t appear until later 2020 and Qualcomm will not release its second-generation Snapdragon X55 5G modem until late 2019. The new chip will support all major spectrum types and bands. Qualcomm claims it is capable of 7Gbps downloads. Until then, the wireless carriers will jockey for customers and mind share.

The providers desperately need 5G to boost smartphone sales. The smartphone market is saturated. Deloitte found (PDF) that 80% of people in developed nations now own a smartphone and wait up to 4 years to replace their device – a significant increase from the 2-year refresh rate in 2011-12.

Related articles

 

Ralph Bach has been in IT long enough to know better and has blogged from his Bach Seat about IT, careers, and anything else that catches his attention since 2005. You can follow him on LinkedInFacebook, and Twitter. Email the Bach Seat here.

Category: Uncategorized | Tags: , , , , , , , ,
| October 7, 2016
Comments Off on AT&T Tries Broadband over Powerline

AT&T Tries Broadband over Powerline

AT&T Tries Broadband over PowerlineIt’s alive. It’s alive! BPL has risen from dead. Longtime readers of the Bach Seat, know the history of Broadband over Powerline. I covered it many years ago here, here, and here. Imagine my surprise when there were a number of articles popping up all over the interwebs touting mega-telecom AT&T’s (T) try at BPL 10 years after everybody else gave up on the technology.

Broadband over PowerlineComputerWorld described this latest incarnation of BPL from AT&T as a low-cost, high-speed wireless internet technology. This time Broadband over Powerline relies on plastic antennas positioned along medium-voltage power lines and not through the conductive materials inside the power lines. FierceTelecom says that AT&T will attach the plastic antennas to the power lines and serve as a mesh network to distribute signals to homes and businesses. The Project AirGig low-cost plastic antennas and devices will regenerate millimeter wave (mmWave) signals. Millimeter-wave technology relies on electromagnetic waves that are longer than x-rays but shorter than radio waves (they are found in the 10 mm to 1 mm range and are also known as extremely high-frequency waves according to New Atlas. The EHF waves can be used for 4G LTE and 5G multi-gigabit mobile and fixed deployments.

John Donovan, chief strategy officer and group president of AT&T technology and operations, told FierceTelecom that Project AirGig delivers last-mile access without any new FTTH technology and is flexible enough to be configured with small cells or distributed antenna systems.

Broadband over PowerlineTo test the technology, AT&T is looking for a place somewhere in the next year with a favorable regulatory environment, since the carrier would need to partner with an existing electric utility. John Donovan, chief strategy officer for AT&T said the trial could be in an area where existing broadband is expensive, even in the U.S.

The AirGig project relies on over 100 patents, according to an AT&T statement. There is no direct electrical connection to the power lines, although network components could receive their needed power through inductive wireless electricity from the near by power lines, AT&T Chief Technology Officer Andre Fuetsch explained to Computerworld.

ATT logoAT&T said the testing will decide what frequency AirGig will use for commercial deployment, which could occur sometime around 2020 after the carrier rolls out 5G wireless. The frequency AT&T uses will affect the range of the signal and the speed, as well as whether it is over a licensed or unlicensed band. This decision is important if AT&T plans to use BPL as another weapon in its fight with Google Fiber. Earlier versions of Broadband over Powerline were incapable of delivering the Google (GOOG) promised Gigabit of Internet access.

“It’s a transformative technology that delivers low-cost and multi-gigabit speeds using power lines,” AT&T’s Donovan said, “There’s no need for enhancements for new towers, and it’s over existing infrastructure.”

Google (GOOG) promised Gigabit of Internet accessAirGig has already been tested in outdoor locations on-campus settings. “We’ve had it up and running 4k video and cameras on campuses for quite some time,” Mr. Donovan said.

Besides using the AirGig technology as an alternative broadband service delivery option, for urban, rural, and under-served markets AT&T wants to convince the electrical utility industry to apply AirGig technology to their unique needs. ComputerWorld says utility companies would be able to use the technology to help spot problems on their power lines from something like a downed tree or cracks in the cable sheath.

rb-

New Atlas points out that earlier this year, a millimeter-wave technology system set a new world record for wireless data transmission by sending data at 6 Gbps. The technology is also showing up in other applications, including heart-rate monitors, car-safety systems, and luggage scanners.

AirGig could be profitable for AT&T. If they can make a deal with an electrical company, they can avoid expensive make ready. Which Google Fiber is struggling mightily with. By using power lines, AirGig avoids the cost of digging trenches to lay fiber optic cable.

Still, questions remain about how this version of Broadband over Powerline will do in the real world.

  • What impact will heavy rain, snow or ice have on the signal?
  • What if a tree branch falls on a power line or the lines are swinging in the wind?
  • Since mmWave transmissions need a direct line-of-sight between antennae, what happens when critters like birds or squirrels decide to perch on the antennae? Will that lead to an outage?

The ham radio lobby will likely be up in arms again when they find AT&T still likes the idea of BPL in the 30-300 GHz bands. The ARRL was a key player in killing BPL 1.0.

 

Related articles

 

Ralph Bach has been in IT long enough to know better and has blogged from his Bach Seat about IT, careers, and anything else that catches his attention since 2005. You can follow him on LinkedInFacebook, and Twitter. Email the Bach Seat here.

Category: Uncategorized | Tags: , , , , , , , , , , , , , , ,