New Technology – February 2017

grapheneThere has been so much going on in the telecom industry lately that I haven’t published a blog examining promising new technologies for a while. Here are a few new breakthroughs that ought to eventually affect our industry:

Metal that Conducts Electricity but not Heat. Physicists at the Lawrence Berkeley National Lab and UC Berkeley have found a metal that contradicts the Wiedermann-Franz Law.  This Law states that good conductors of electricity will also be proportionately good conductors of heat. The physicists were working with vanadium dioxide and unexpectedly discovered this property. There are a few other materials that are much better at conducting electricity than heat, but they only do so at temperatures a few hundred degrees below zero. It appears vanadium dioxide can do this at room temperatures. This property is derived from the fact that electrons move through the metal in a synchronized manner which is normally observed only in fluids, instead of individually which is normally observed in metals.

There is great potential for a material with this property – it could be used as an insulator in computers to keep components cool and to drastically lower the cooling costs experienced in data centers. On a more macro level this could lead to better insulation in homes and appliances and could drastically improve energy efficiency in a wide range of applications.

Superconductor Graphene. Researchers at the University of Cambridge in the UK have found a way to induce superconductivity in graphene. Today all superconducting materials only function at temperatures below -454 degrees Fahrenheit. But their research indicates superconducting graphene will work at much higher temperatures. The researchers created superconducting properties by layering graphene only on an underlying sheet of metal.

Superconduction is a big deal, because in the ultimate state a superconductor passes electrons with zero resistance. Compare that to normal materials, such as our electric grid that loses 7% of generated power getting to homes, and the difference is remarkable.  Finding a room-temperature superconductor would be a huge breakthrough because it could mean electric transmissions with no power losses and an end to the heat generated in electronics and appliances that comes from resistance.

Mass Producing Graphene. Scientists at Kansas State have found a cheap way to mass produce graphene. They discovered the process when working with carbon soot aerosol gels. The process is simple and only requires hydrocarbon gas, oxygen and a spark plug. The gases are forced into a chamber and graphene is formed with a spark. This is a low-power way to make graphene since it only needs a spark rather than continuous power.

Until now graphene has been expensive to make in quantities greater than milligrams and the process required caustic chemicals. With this method it’s easy to make graphene in gram quantities and the process ought to be scalable to much larger quantities.

Better Use of Wireless Spectrum. Engineers at UCLA have found a technique that might allow better use of wireless spectrum. They have found a way to use a tiny device called a circulator that allows a chip to use both incoming and outgoing signals of a given spectrum at the same time. Today’s technology only uses spectrum in one direction since dual use of spectrum has caused interference.

Circulators have been tried before, but earlier devices used magnetic materials which can’t be incorporated into chips. The prototype they built uses coaxial cables to route the signals through non-magnetic materials and they believe the design can be built directly into silicon.

The circulator works by sequentially switching signals using different paths in a similar manner that a busy train station can have trains coming in going in both directions. The design uses six transmission lines and five switches which are turned off and on sequentially to allow incoming and outgoing signals to pass each other without interference.

This would be a big breakthrough for cellphones since it would allow for better use of the spectrum. This wouldn’t increase data speeds, but would allow a cell site to handle more phones at the same time.


New Technology – June 2016

There is a lot of recent news of technological breakthroughs that ought to have some an on telecom and broadband.

Faster Microwave Radios. A collaboration of researchers working for ACCESS (Advanced E Band Satellite Link Studies) in Germany has created a long-range microwave link at 6 Gbps speeds. The technology uses the very high E band frequencies at 71 – 76 GHz and in testing were able to create a data path between radios that were 23 miles apart. It’s the very short length of the radio waves at this frequency that allow for the very fast data rates.

The radios rely on transistor technology from Fraunhofer IAF, a firm that has been involved in several recent high-bandwidth radio technologies. The transmitting radio broadcasts at a high-power of 1 watt while the receivers are designed to detect and reconstruct very weak signals.

When perfected this could provide a lower cost way to provide bandwidth links to remote locations like towns situated in rough terrain or cellular and other radio towers located on mountaintops. This is a significant speed breakthrough for point-to-point microwaves at almost six times the speed of other existing microwave technologies.

Smarter Chip Processing. A team at MIT’s Computer Science and Artificial Intelligence Laboratory have developed a programming technique to make much better use of denser computer chips. In theory, a 64-core chip ought to be nearly 64 times faster than one with a single core, but in practice that has not been the case. Since most computer programs run sequentially (instructions and decision trees are examined one at a time, in order) most programs do not run much faster on denser chips.

The team created a new chip design they call Swarm that will speed up parallel processing and that will also make it easier to write the code for denser chips. In early tests, programs run on the swarm chip have been 3 to 18 times faster while also requiring as little as 10% of the code needed for normal processing.

1,000 Processor Chip. And speaking of denser chips, scientists at the University of California at Davis Department of Electrical and Computer Engineering have developed the first chip that contains over 1,000 separate processors. The chip has a maximum computation rate of 1.78 trillion instructions per second.

They are calling it the KiloCore chip and it’s both energy efficient and the highest clock rate chip ever developed. The chip uses IBM’s 32 nanometer technology. Each chip can run separate programming or they can be used in parallel. The scientists envision using a programming technique called the single-instruction-multiple-data approach that can break applications down into small discrete steps so that they can be processed simultaneously.

Faster Graphene Chips. Finally, US-Army funded researchers at MIT’s Institute for Soldier Nanotechnologies have developed a technology that could theoretically make chips as much as 1 million times faster than today. The new technology uses graphene and relies on the phenomenon that graphene can be used to slow light below the speed of electrons. This slowed-down light emits ‘plasmons’ of intense light that create what the scientists called an optic boom (similar to a sonic boom in air).

These plasmons could be used to greatly speed up the transmission speeds within computer chips. They have found that the optic booms can push data through graphene at about 1/300th the speed of light, a big improvement over photons through silicon.

The researchers have been able to create and control the plasmon bursts and are hoping to have a working graphene chip using the technology within two or three years.

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