 |
|
NIST demonstrates 'universal' programmable quantum processor
November 16, 2009BOULDER, Colo.- Physicists at the National Institute of Standards and Technology (NIST) have demonstrated the first "universal" programmable quantum information processor able to run any program allowed by quantum mechanics-the rules governing the submicroscopic world-using two quantum bits (qubits) of information. The processor could be a module in a future quantum computer, which theoretically could solve some important problems that are intractable today.
The NIST demonstration, described in Nature Physics,* marks the first time any research group has moved beyond demonstrating individual tasks for a quantum processor-as done previously at NIST and elsewhere-to perform programmable processing, combining enough inputs and continuous steps to run any possible two-qubit program.
The NIST team also analyzed the quantum processor with the methods used in traditional computer science and electronics by creating a diagram of the processing circuit and mathematically determining the 15 different starting values and sequences of processing operations needed to run a given program. "This is the first time anyone has demonstrated a programmable quantum processor for more than one qubit," says NIST postdoctoral researcher David Hanneke, first author of the paper. "It's a step toward the big goal of doing calculations with lots and lots of qubits. The idea is you'd have lots of these processors, and you'd link them together."
The NIST processor stores binary information (1s and 0s) in two beryllium ions (electrically charged atoms), which are held in an electromagnetic trap and manipulated with ultraviolet lasers. Two magnesium ions in the trap help cool the beryllium ions.
NIST scientists can manipulate the states of each beryllium qubit, including placing the ions in a "superposition" of both 1 and 0 values at the same time, a significant potential advantage of information processing in the quantum world. Scientists also can "entangle" the two qubits, a quantum phenomenon that links the pair's properties even when the ions are physically separated.
With these capabilities, the NIST team performed 160 different processing routines on the two qubits. Although there are an infinite number of possible two-qubit programs, this set of 160 is large and diverse enough to fairly represent them, Hanneke says, making the processor "universal." Key to the experimental design was use of a random number generator to select the particular routines that would be executed, so all possible programs had an equal chance of selection. This approach was chosen to avoid bias in testing the processor, in the event that some programs ran better or produced more accurate outputs than others.
Ions are among several promising types of qubits for a quantum computer. If they can be built, quantum computers have many possible applications such as breaking today's most widely used encryption codes, such as those that protect electronic financial transactions. In addition to its possible use as a module of a quantum computer, the new processor might be used as a miniature simulator for interactions in any quantum system that employs two energy levels, such as the two-level ion qubit systems that represent energy levels as 0s and 1s. Large quantum simulators could, for example, help explain the mystery of high-temperature superconductivity, the transmission of electricity with zero resistance at temperatures that may be practical for efficient storage and distribution of electric power.
The new paper is the same NIST research group's third major paper published this year based on data from experiments with trapped ions. They previously demonstrated sustained quantum information processing (http://www.nist.gov/public_affairs/releases/ ion_trap_computers080609.html) and entanglement in a mechanical system similar to those in the macroscopic everyday world (http://www.nist.gov/public_affairs/ releases/jost/jost_060309.html). NIST quantum computing research contributes to advances in national priority areas, such as information security, as well as NIST mission work in precision measurement and atomic clocks.
In the latest NIST experiments reported in Nature Physics, each program consisted of 31 logic operations, 15 of which were varied in the programming process. A logic operation is a rule specifying a particular manipulation of one or two qubits. In traditional computers, these operations are written into software code and performed by hardware.
The programs did not perform easily described mathematical calculations. Rather, they involved various single-qubit "rotations" and two-qubit entanglements. As an example of a rotation, if a qubit is envisioned as a dot on a sphere at the north pole for 0, at the south pole for 1, or on the equator for a balanced superposition of 0 and 1, the dot might be rotated to a different point on the sphere, perhaps from the northern to the southern hemisphere, making it more of a 1 than a 0.
Each program operated accurately an average of 79 percent of the time across 900 runs, each run lasting about 37 milliseconds. To evaluate the processor and the quality of its operation, NIST scientists compared the measured outputs of the programs to idealized, theoretical results. They also performed extra measurements on 11 of the 160 programs, to more fully reconstruct how they ran and double-check the outputs.
As noted in the paper, many more qubits and logic operations will be required to solve large problems. A significant challenge for future research will be reducing the errors that build up during successive operations. Program accuracy rates will need to be boosted substantially, both to achieve fault-tolerant computing and to reduce the computational "overhead" needed to correct errors after they occur, according to the paper.
As a non-regulatory agency of the U.S. Department of Commerce, NIST promotes U.S. innovation and industrial competitiveness by advancing measurement science, standards and technology in ways that enhance economic security and improve our quality of life.
National Institute of Standards and Technology (NIST)
The NIST processor stores binary information (1s and 0s) in two beryllium ions (electrically charged atoms), which are held in an electromagnetic trap and manipulated with ultraviolet lasers. Two magnesium ions in the trap help cool the beryllium ions.
NIST scientists can manipulate the states of each beryllium qubit, including placing the ions in a "superposition" of both 1 and 0 values at the same time, a significant potential advantage of information processing in the quantum world. Scientists also can "entangle" the two qubits, a quantum phenomenon that links the pair's properties even when the ions are physically separated.
With these capabilities, the NIST team performed 160 different processing routines on the two qubits. Although there are an infinite number of possible two-qubit programs, this set of 160 is large and diverse enough to fairly represent them, Hanneke says, making the processor "universal." Key to the experimental design was use of a random number generator to select the particular routines that would be executed, so all possible programs had an equal chance of selection. This approach was chosen to avoid bias in testing the processor, in the event that some programs ran better or produced more accurate outputs than others.
Ions are among several promising types of qubits for a quantum computer. If they can be built, quantum computers have many possible applications such as breaking today's most widely used encryption codes, such as those that protect electronic financial transactions. In addition to its possible use as a module of a quantum computer, the new processor might be used as a miniature simulator for interactions in any quantum system that employs two energy levels, such as the two-level ion qubit systems that represent energy levels as 0s and 1s. Large quantum simulators could, for example, help explain the mystery of high-temperature superconductivity, the transmission of electricity with zero resistance at temperatures that may be practical for efficient storage and distribution of electric power.
The new paper is the same NIST research group's third major paper published this year based on data from experiments with trapped ions. They previously demonstrated sustained quantum information processing (http://www.nist.gov/public_affairs/releases/ ion_trap_computers080609.html) and entanglement in a mechanical system similar to those in the macroscopic everyday world (http://www.nist.gov/public_affairs/ releases/jost/jost_060309.html). NIST quantum computing research contributes to advances in national priority areas, such as information security, as well as NIST mission work in precision measurement and atomic clocks.
In the latest NIST experiments reported in Nature Physics, each program consisted of 31 logic operations, 15 of which were varied in the programming process. A logic operation is a rule specifying a particular manipulation of one or two qubits. In traditional computers, these operations are written into software code and performed by hardware.
The programs did not perform easily described mathematical calculations. Rather, they involved various single-qubit "rotations" and two-qubit entanglements. As an example of a rotation, if a qubit is envisioned as a dot on a sphere at the north pole for 0, at the south pole for 1, or on the equator for a balanced superposition of 0 and 1, the dot might be rotated to a different point on the sphere, perhaps from the northern to the southern hemisphere, making it more of a 1 than a 0.
Each program operated accurately an average of 79 percent of the time across 900 runs, each run lasting about 37 milliseconds. To evaluate the processor and the quality of its operation, NIST scientists compared the measured outputs of the programs to idealized, theoretical results. They also performed extra measurements on 11 of the 160 programs, to more fully reconstruct how they ran and double-check the outputs.
As noted in the paper, many more qubits and logic operations will be required to solve large problems. A significant challenge for future research will be reducing the errors that build up during successive operations. Program accuracy rates will need to be boosted substantially, both to achieve fault-tolerant computing and to reduce the computational "overhead" needed to correct errors after they occur, according to the paper.
As a non-regulatory agency of the U.S. Department of Commerce, NIST promotes U.S. innovation and industrial competitiveness by advancing measurement science, standards and technology in ways that enhance economic security and improve our quality of life.
National Institute of Standards and Technology (NIST)
Quantum Computer Current Events and Quantum Computer News RSSPrinceton scientist makes a leap in quantum computing
A major hurdle in the ambitious quest to design and construct a radically new kind of quantum computer has been finding a way to manipulate the single electrons that very likely will constitute the new machines' processing components or "qubits."
Turning down the noise in quantum data storage
Researchers who hope to create quantum computers are currently investigating various methods to store data.
Quantum computer calculates exact energy of molecular hydrogen
In an important first for a promising new technology, scientists have used a quantum computer to calculate the precise energy of molecular hydrogen. This groundbreaking approach to molecular simulations could have profound implications not just for quantum chemistry, but also for a range of fields from cryptography to materials science.
Field experiment on a robust hierarchical metropolitan quantum cryptography network
Key Laboratory of Quantum Information (CAS), University of Science and Technology of China has recently demonstrated a metropolitan Quantum Cryptography Network (QCN) for Government Administration in Wuhu, China. Because of its scientific significance and social impact, the project is reported in Volume 54, Issue 17 (September, 2009) of the Chinese Science Bulletin authored by Fang-xing Xu et al.
Diamonds may be the ultimate MRI probe, say Quantum physicists
Diamonds, it has long been said, are a girl's best friend. But a research team including a physicist from the National Institute of Standards and Technology (NIST) has recently found that the gems might turn out to be a patient's best friend as well.
Experiments at UCSB push quantum mechanics to higher levels
Scientists at UC Santa Barbara have devised a new type of superconducting circuit that behaves quantum mechanically -- but has up to five levels of energy instead of the usual two. The findings are published in the August 7 issue of Science.
A Police Woman Fights Quantum Hacking and Cracking
The first desktop computers changed the way we managed data forever. Three decades after their introduction, we rely on them to manage our time, social life and finances - and to keep this information safe from prying eyes and online predators.
Physicists find way to control individual bits in quantum computers
Physicists at the National Institute of Standards and Technology (NIST) have overcome a hurdle in quantum computer development, having devised* a viable way to manipulate a single "bit" in a quantum processor without disturbing the information stored in its neighbors.
Scientists create first electronic quantum processor
A team led by Yale University researchers has created the first rudimentary solid-state quantum processor, taking another step toward the ultimate dream of building a quantum computer.
Manipulating light on a chip for quantum technologies
A team of physicists and engineers at Bristol University has demonstrated exquisite control of single particles of light - photons - on a silicon chip to make a major advance towards long-sought-after quantum technologies, including super-powerful quantum computers and ultra-precise measurements.
More Quantum Computer Current Events and Quantum Computer News Articles
 |
An Introduction to Quantum Computing by Phillip Kaye (Author), Raymond Laflamme (Author), Michele Mosca (Author) This concise, accessible text provides a thorough introduction to quantum computing - an exciting emergent field at the interface of the computer, engineering, mathematical and physical sciences. Aimed at advanced undergraduate and beginning graduate students in these disciplines, the text is technically detailed and is clearly illustrated throughout with diagrams and exercises. Some prior knowledge of linear algebra is assumed, including vector spaces and inner products. However, prior familiarity with topics such as tensor products and spectral decomposition is not required, as the necessary material is reviewed in the text. |
 |
Quantum Computing for Computer Scientists by Noson S. Yanofsky (Author), Mirco A. Mannucci (Author) The multidisciplinary field of quantum computing strives to exploit some of the uncanny aspects of quantum mechanics to expand our computational horizons. Quantum Computing for Computer Scientists takes readers on a tour of this fascinating area of cutting-edge research. Written in an accessible yet rigorous fashion, this book employs ideas and techniques familiar to every student of computer science. The reader is not expected to have any advanced mathematics or physics background. After presenting the necessary prerequisites, the material is organized to look at different aspects of quantum computing from the specific standpoint of computer science. There are chapters on computer architecture, algorithms, programming languages, theoretical computer science, cryptography, information... |
 |
A Shortcut Through Time: The Path to the Quantum Computer by George Johnson (Author) In this remarkably illustrative and thoroughly accessible look at one of the most intriguing frontiers in science and computers, award-winning New York Times writer George Johnson reveals the fascinating world of quantum computing—the holy grail of super computers where the computing power of single atoms is harnassed to create machines capable of almost unimaginable calculations in the blink of an eye. As computer chips continue to shrink in size, scientists anticipate the end of the road: A computer in which each switch is comprised of a single atom. Such a device would operate under a different set of physical laws: The laws of quantum mechanics. Johnson gently leads the curious outsider through the surprisingly simple ideas needed to understand this dream, discussing the... |
 |
James Bond 007: Quantum of Solace by Activision Inc. 007 Quantum of Solace PS3 |
 |
Quantum Super DLTtape II 300/600GB Tape Cartridge by Quantum Eide Super DLTtape II is the most advanced media in its class. The Super DLTtape II magnetic recording layer is thinner and its magnetic particle size is smaller than the previous generation to boost tape drive performance with superior media capacity and superior reliability. The Super DLTtape II media establishes a new standard in performance and media management and is ideally suited for the most demanding and data-intensive automation, enterprise and stand-alone DLTtape environments. |
 |
James Bond 007: Quantum of Solace by Activision Can you be the next James Bond? Coldly efficient dangerous the new Bond is the ultimate weapon in today's ruthless world of international espionage. Blending first person shooting and third person action, Quantum of Solace puts you in control of Bond's greatest weapon his mind. You must think like Bond and intelligently use the map and situation to your advantage. Confront enemies in a variety of ways: take them head on, fire from behind cover or sneak up silently and eliminate them with a variety of special takedown moves. Based on Quantum of Solace and Casino Royale, Quantum of Solace the Game puts you in the dangerous world of international espionage and intrigue. |
 |
Quantum Leap - The Complete Fourth Season Starring: Scott Bakula, Dean Stockwell, Deborah Pratt, Dennis Wolfberg, W.K. Stratton Directed By: Anita W. Addison, Bob Hulme, Chris Ruppenthal, Eric Laneuville, James Whitmore Jr. Take a trip through time with the daring Dr. Sam Beckett (Scott Bakula) and his hilarious hologram guide, Al (Dean Stockwell), in all 22 extraordinary, groundbreaking episodes of Quantum Leap: The Complete Fourth Season. It’s adventure like you’ve never seen, with each amazing episode from this eight-time Emmy-nominated season now digitally remastered for incredible picture quality. Journey back as Sam and Al survive a hurricane, trail a murderer, make a monkey out of themselves and even switch roles! With each "leap" into another identity, Sam hopes to find some insight into the jump that will finally take him home. And now, fans can spend more time with Sam and Al with an exclusive bonus episode from the Fifth Season. You won’t want to miss a minute of the adventure! |
 |
Learning Resources - Quantum Big Screen Microscope by Learning Resources This big seven-inch screen microscope projects a whopping 10x, 20x, or 40x clear image. Includes assortment of accessories, glare-reducing shield and Snap-Tight tray to hold components. Operates with three "C" batteries (not included) or AC adapter (sold separately). |
 |
Quantum of Solace David Arnold (Composer) Quantum of Solace continues the high octane adventures of Daniel Craig as James Bond. Directed by Marc Fisher, this 22nd installation in the 007 franchise hits theaters on October 31st, 2008 in Europe and November 14th in the US. This film features music by composer David Arnold and the new single 'Another Way To Die' by Jack White (White Stripes) and Alicia Keys, a first ever duet for a James Bond flick. The Quantum of Solace soundtrack will include the movie score and this new single. David Arnold is a Grammy-winning English film composer, best known for scoring five James Bond films including the score for Casino Royale and the blockbuster Independence Day. |
 |
Quantum Computer Science: An Introduction by N. David Mermin (Author) In the 1990's it was realized that quantum physics has some spectacular applications in computer science. This book is a concise introduction to quantum computation, developing the basic elements of this new branch of computational theory without assuming any background in physics. It begins with an introduction to the quantum theory from a computer-science perspective. It illustrates the quantum-computational approach with several elementary examples of quantum speed-up, before moving to the major applications: Shor's factoring algorithm, Grover's search algorithm, and quantum error correction. The book is intended primarily for computer scientists who know nothing about quantum theory, but will also be of interest to physicists who want to learn the theory of quantum computation, and... |
| © 2010 BrightSurf.com |