Menu

Blog

Archive for the ‘computing’ category: Page 696

Mar 5, 2017

Are We Ready for Cyborgs? The Tech Is on Its Way

Posted by in categories: computing, cyborgs

Are we ready for cyborgs? More specifically, people with implants that enhance beyond the superficially cosmetic and into the realms of evolved beings?

Jorge Pelegrín-Borondo (Universidad de La Rioja), Eva Reinares-Lara (Universidad Rey Juan Carlos) and Cristina Olarte-Pascual (Universidad de La Rioja), in cooperation with Professor Kiyoshi Murata, from Meiji University in Tokyo, believe society is ready for this melding of (hu)man and machine.

The Spanish academics’ report “Assessing the acceptance of technological implants (the cyborg): Evidences and challenges” has just been released in the scientific journal Computers in Human Behavior. The report shows a significant proportion of those surveyed are comfortable with the coming cyborg modifications. The group are also collaborating with other academics across the world, including Professor Kiyoshi Murata, for a comparative cross-cultural study roundtable at the 2017 ETHICOMP conference this summer in Turin, Italy.

Continue reading “Are We Ready for Cyborgs? The Tech Is on Its Way” »

Mar 5, 2017

Scientists prove they can store 215 petabytes in a single gram of DNA, retrieve it error free

Posted by in categories: biotech/medical, computing

DNA storage is the wave of the future as scientists have proven they can store incredible amounts of data in just a few grams of nucleic acid, and retrieve the data countless times, error-free.

Read more

Mar 3, 2017

Researchers demonstrate new type of laser

Posted by in categories: biotech/medical, computing, quantum physics

Lasers are everywhere nowadays: Doctors use them to correct eyesight, cashiers to scan your groceries, and quantum scientist to control qubits in the future quantum computer. For most applications, the current bulky, energy-inefficient lasers are fine, but quantum scientist work at extremely low temperatures and on very small scales. For over 40 years, they have been searching for efficient and precise microwave lasers that will not disturb the very cold environment in which quantum technology works.

A team of researchers led by Leo Kouwenhoven at TU Delft has demonstrated an on-chip laser based on a fundamental property of superconductivity, the ac Josephson effect. They embedded a small section of an interrupted superconductor, a Josephson junction, in a carefully engineered on-chip cavity. Such a device opens the door to many applications in which microwave radiation with minimal dissipation is key, for example in controlling qubits in a scalable computer.

The scientists have published their work in Science on the 3rd of March.

Read more

Mar 1, 2017

Mathematician breaks down how to defend against quantum computing attacks

Posted by in categories: computing, encryption, internet, mathematics, quantum physics

The encryption codes that safeguard internet data today won’t be secure forever.

Future quantum computers may have the and algorithms to crack them.

Nathan Hamlin, instructor and director of the WSU Math Learning Center, is helping to prepare for this eventuality.

Read more

Feb 28, 2017

Researchers Have Directly Tested Two Quantum Computing Technologies

Posted by in categories: computing, particle physics, quantum physics

If you aren’t already, you’re likely soon to find yourself looking forward to the day when quantum computers will replace regular computers for every day use. The computing power of quantum computers is immense compared to what regular desktops or laptops can do. The downside is, current quantum computing technology are limited by the bulky frameworks and extreme conditions they require in order to function.

Quantum computers need specialized setups in order to sustain and keep quantum bits — the heart of quantum computing — working. These “qubits” are particles in a quantum state of superposition, which allows them to encode and transmit information as 0s and 1s simultaneously. Most computers run on binary bit systems which use either 0s or 1s. Since quantum computers can use both at the same time, they can process more information faster. That being said, Sustaining the life of qubits is particularly difficult, but researchers are investigating quantum computing studies are trying to find ways to prolong the life of qubits using various techniques.

Read more

Feb 28, 2017

Existence of a new quasiparticle demonstrated

Posted by in categories: computing, information science, particle physics

How do molecules rotate in a solvent? Answering this question is complicated, since molecular rotation is perturbed by a very large number of surrounding atoms. For a long time, large-scale computer simulations have been the main approach to model molecule-solvent interactions. However, they are extremely time consuming and sometimes infeasible. Now, Mikhail Lemeshko from the Institute of Science and Technology Austria (IST Austria) has proven that angulons—a certain type of quasiparticle he proposed two years ago—do, in fact, form when a molecule is immersed in superfluid helium. This offers a quick and simple description for rotation of molecules in solvents.

In physics, the concept of quasiparticles is used as a technique to simplify the description of many-particle systems. Namely, instead of modeling strong interactions between trillions of individual particles, one identifies building blocks of the system that are only weakly interacting with one another. These building blocks are called quasiparticles and might consist of groups of particles. For example, to describe air bubbles rising up in water from first principles, one would need to solve an enormous set of equations describing the position and momentum of each water molecule. On the other hand, the bubbles themselves can be treated as individual particles—or quasiparticles—which drastically simplifies the description of the system. As another example, consider a running horse engulfed in a cloud of dust. One can think of it as a quasiparticle consisting of the horse itself and the dust cloud moving along with it.

Read more

Feb 27, 2017

An ultra-low-power artificial synapse for neural-network computing

Posted by in categories: computing, neuroscience

(Left) Illustration of a synapse in the brain connecting two neurons. (Right) Schematic of artificial synapse (ENODe), which functions as a transistor. It consists of two thin, flexible polymer films (black) with source, drain, and gate terminals, connected by an electrolyte of salty water that permits ions to cross. A voltage pulse applied to the “presynaptic” layer (top) alters the level of oxidation in the “postsynaptic layer” (bottom), triggering current flow between source and drain. (credit: Thomas Splettstoesser/CC and Yoeri van de Burgt et al./Nature Materials)

Stanford University and Sandia National Laboratories researchers have developed an organic artificial synapse based on a new memristor (resistive memory device) design that mimics the way synapses in the brain learn. The new artificial synapse could lead to computers that better recreate the way the human brain processes information. It could also one day directly interface with the human brain.

The new artificial synapse is an electrochemical neuromorphic organic device (dubbed “ENODe”) — a mixed ionic/electronic design that is fundamentally different from existing and other proposed resistive memory devices, which are limited by noise, required high write voltage, and other factors*, the researchers note in a paper published online Feb. 20 in Nature Materials.

Continue reading “An ultra-low-power artificial synapse for neural-network computing” »

Feb 26, 2017

How Nobel physicists could revolutionise computers

Posted by in categories: computing, particle physics

I remember a year ago when this 1st came out; nice they are highlighting 1 yr later as a reminder.


British scientists David Thouless, Duncan Haldane and Michael Kosterlitz won this year’s Nobel Prize in Physics “for theoretical discoveries of topological phase transitions and topological phases of matter”. The reference to “theoretical discoveries” makes it tempting to think their work will not have practical applications or affect our lives some day. The opposite may well be true.

To understand the potential, it helps to understand the theory. Most people know that an atom has a nucleus in the middle and electrons orbiting around it. These correspond to different energy levels. When atoms group into substances, all the energy levels of each atom combine into bands of electrons. Each of these so-called energy bands has space for a certain number of electrons. And between each band are gaps in which electrons can’t flow.

Continue reading “How Nobel physicists could revolutionise computers” »

Feb 26, 2017

Quantum Computing with Spacetime Curvature?

Posted by in categories: computing, quantum physics

General Relativity and quantum theory, the two pillars of modern physics, although notoriously difficult to reconcile, may beautifully work together, as a new paper suggests. Moreover, the spacetime curvature and twisting create, manipulate and communicate quantum information encoded in light.

Read more

Feb 26, 2017

Holographic Atomic Memory Produces Photons On Demand

Posted by in category: computing

WARSAW, Poland, Feb. 10, 2017 — A device that is able to generate single photons on demand in groups of several dozen or more could help scientists overcome one of the fundamental obstacles facing the construction of quantum computers.

Read more