While greater bandwidth in the 300GHz and above band has been known for a while it is pointless because the range makes it a chocolate teapot.

Some researchers have managed to hit 100 Gbps but when it only works for a few centimeters it is not commercially viable.

Now boffins at the Tokyo Institute of Technology have got the technology to provide a great 34 Gbps speed with a decent range.

Naoto Oshimo, one of the scientists behind this latest test, said that “device performance is almost sufficient for short-distance wireless communication such as KIOSK downloads, which might be its first application”. By that they mean that they have managed 10 metres, almost OK for home use.

Oshimo believes that this technology will scale hugely in terms of the speed as well, and we could eventually be looking at topping the 1Tbps mark.

Courtesy-Fud

Basically this means that the hardware can be used by the OPNFV collaborative open source community to accelerate the delivery of cloud-enabled networks and applications.

Nokia said the OPNFV Lab will be a testbed for NFV developers and accelerates the introduction of commercial open source NFV products and services. Developers can test carrier-grade NFV applications for performance and availability.

Nokia is making its AirFrame Data Center Solution available as a public OPNFV Lab with the support of Intel, which is providing Intel Xeon processors and solid state drives to give communications service providers the advantage of testing OPNFV projects on the latest and greatest server and storage technologies.

The Nokia AirFrame Data Center Solution is 5G-ready and Nokia said it was the first to combine the benefits of cloud computing technologies to meet the stringent requirements of the telco world. It’s capable of delivering ultra-low latency and supporting the kinds of massive data processing requirements that will be required in 5G.

Morgan Richomme, NFV network architect for Innovative Services at Orange Labs, OPNFV Functest PTL, in a release. “NFV interoperability testing is challenging, so the more labs we have, the better it will be collectively for the industry.”

AT&T has officially added Nokia to its list of 5G lab partners working to define 5G features and capabilities. It’s also working with Intel and Ericsson.

Courtesy-Fud

The researchers have worked out that slowing the speed of light to the extent that it moves slower than flowing electrons can create an “optical boom”, the optical equivalent of a sonic boom.

Slowing the speed of light is no mean feat, but the clever folks at MIT managed it by using the honeycomb shape of carbon to slow photons to slow photons to several hundredths of their normal speed in a free space, explained researcher Ido Kaminer.

Meanwhile, the characteristics of graphene speed up electrons to a million metres a second, or around 1/300 of the speed of light in a vacuum.

The optical boom is caused when the electrons passing though the graphene reach the speed of light, effectively breaking its barrier in the carbon honeycomb and causing a shockwave of light.

As electrons move faster than the trapped light, they bleed plasmons, a form of virtual particle that represents the oscillation of electrons on the graphene’s surface.

Effectively, it is the equivalent of turning electricity into light. This is nothing new – Thomas Edison did it a century ago with fluorescent tubes – but it can efficiently and controllably generate plasmons at a scale that works with microchip technology.

The discovery could allow chip components to be made from graphene to enable the creation of light-based circuits. These circuits could be the next step in the evolution of chip and computing technology, as the transfer of data through light is far faster than using electrons in today’s chips, even the fast pixel-pushing ones.

So much faster that it’s “six orders of magnitude higher than what is used in electronics”, according to Kaminer. That’s up to a million times faster in plain English.

“There’s a lot of excitement about graphene because it could be easily integrated with other electronics,” said physics professor Marin Soljačić, a researcher on the project, who is confident that MIT can turn this theoretical experiment into a working system. “I have confidence that it should be doable within one to two years.”

This is a pretty big concept and almost sci-fi stuff, but we’re always keen to see smaller and faster chips. It also shows that the future tech envisioned by the world of sci-fi may not be that far away.

Courtesy-TheInq

“This is the most advanced arm in the world,” Johnny Matheny, who lost his left arm to cancer in 2008 and demonstrated the robotic arm for DARPA, said in a statement. “This one can do anything your natural arm can do, with the exception of the Vulcan V. But unless I meet a Vulcan, I won’t need it.”

Matheny showed the arm during Demo Day for the Defense Advanced Research Projects Agency, the military’s research unit, which was held Wednesday at the Pentagon. The device was developed at the Research and Exploratory Development Department at Johns Hopkins Applied Physics Laboratory.

The robotic arm is attached to a piece of metal that is surgically implanted into the bone of the user’s arm in technique called osseointegration. Matheny is the first person in the U.S. to have undergone the procedure, according to the U.S. Army.

The Army called the system a “true man/machine interface.”

The mind-controlled aspect of the arm comes into play via the nerves and muscles in what remains of the user’s arm. Those tissues send signals to the robotic arm, which responds to them as a real arm would.

“This is part of the Revolutionizing Prosthetics Program, where we set out to restore near-natural upper extremity control to our military service members who have lost limbs in service of our country,” said Dr. Justin C. Sanchez, director of the Biological Technologies Office at DARPA, in a statement. “The goal is to control the arm as naturally as possible.”

The robotic arm, according to Sanchez, has the same size, weight, shape and grip strength as an adult biological arm.

Source-http://www.thegurureview.net/aroundnet-category/darpa-shows-off-mind-controlled-robotic-arm.html

The tear downs will start happening soon but our sources very close to the matter said with high certainly that all iPhone SE come with an updated Qualcomm modem.

Intel is still in the run but apparently Apple still felt confident to continue using Qualcomm even for this generation of the phone. A few analysts did suggested that iPhone 7 and beyond might get Intel LTE hardware, but not with iPhone SE.

Back in December, when we originally wrote that Intel got the iPhone SE deal, our sources did suggest that Apple can still change its mind if it doesn’t feel that Intel modem is ready. This might be the case, but in the future, we are quite confident that Apple will get a second LTE supplier at some point, just as it did with different manufacturing fabs.

Having two suppliers will drive the cost down, and for Apple every dollar or cent they save of components means millions more in its pocket. Apple claims “LTE up to 50 percent faster than iPhone 5s,” but it doesn’t give a real number. The iPhone 5S uses MDM9615 that was first introduced in 2011. This modem is at the technology range of Cat 4, X5 modem that Qualcomm ships in its entry level SoCs or as an external component.

We will have to wait for the first teardowns to appear as it is not easy to get to “ LTE up to 50 percent faster than iPhone 5s.” You would need a modem that is capable of 225 Mbps  and the next of potential candidates for the iPhone SE is the MDM 20nm 9×35. Qualcomm calls this modem X7 these days, it use to call it Gobi back in late 2014 and this is a Cat 6, 300 Mbit per second download and 50 Mbit per second upload capable chip.

The fact that Apple continues the exclusive deal with Qualcomm is bad news for Intel, but we are sure that the team blue will keep working on getting inside of iPhone.

Courtesy-Fud

The carrier also announced it is creating a new dedicated network core for IoT connections that can scale far beyond the ability of its existing networks with the intent to reach billions of sensors and devices.

“Continued innovation in smart cities, connected cars and wearables demonstrates that IoT is the future for how we will live and work,” said Mike Lanman, senior vice president of enterprise products at Verizon during an event held at Verizon’s San Francisco Innovation Center. He said Verizon is taking a “holistic approach” to help expand the IoT market from millions of connections to billions. The event was webcast.

Other major wireless carriers, including AT&T, are developing programs to offer a range of services to industries and cities for connecting IoT sensors to wireless networks and then to cloud services for data analysis.

At Verizon, Lanman said the company is working to lower the cost of connecting billions of existing devices that companies have used for years to Verizon’s network. Holding up a new computer chip made by Sequans Communications, an LTE chip maker, he said the chip will provide a “significant reduction in cost…that changes the game.” It will provide 4G LTE connectivity in modules connected to IoT devices to “make the wide-area network more accessible to developers.”

Also, next year Verizon will launch a new IoT core network within its LTE network to provide a “much lower cost” than with Verizon’s existing wired and wireless networks.

“The cost for an IoT module and the cost to connect will both drop dramatically,” Lanman added. “Whether you are connecting your dog or water meters and any other low-payload devices, we’ll handle it through a new IoT core.”

Source-http://www.thegurureview.net/consumer-category/verizon-launches-thingspace-for-iot-development.html

The average download speed on U.S. 4G networks inched up to 10Mbps (bits per second) in the June-August quarter, according to research company OpenSignal. That was an improvement from 9Mbps in the previous quarter, but the country’s global ranking fell from 43rd as users in other countries made much larger gains.

The U.S. was one of the first countries with commercial LTE service when Verizon Wireless launched its network in late 2010. But other countries that adopted the system later started with better technology, and some have secured more frequencies or rolled out enhancements that U.S. carriers haven’t embraced as much, OpenSignal said.

New Zealand scored the highest average speed in the quarter with 36Mbps, coming up from nowhere in the rankings. But perennial standouts like South Korea and Singapore kept getting faster, too. The average LTE speed in Korea is now 29Mbps (up by 4Mbps), and in Singapore it’s 33Mbps, up by 5Mbps.

OpenSignal collects data on cellular performance through a free app that mobile subscribers can use to measure the speed they’re getting and find faster networks. The results announced Wednesday are based on readings from more than 300,000 users worldwide, the company said.

Countries like Hungary, the Dominican Republic and Morocco beat the U.S. in average LTE speed, but they aren’t necessarily smartphone paradises. Mobile users in America can use LTE more of the time, for example, because their carrier’s networks are built out. Subscribers in the U.S. are on LTE 78 percent of the time, on average, making the country No. 10 for what OpenSignal calls “time coverage.” Moroccan LTE may be fast, but 49 percent of the time, users there don’t get it, for example.

Source-http://www.thegurureview.net/mobile-category/u-s-falls-to-55th-place-worldwide-for-lte-speeds.html