Category Archives: Quantum Computer
Graphs are used in mathematics, engineering and computer science, and they are growing as a technology in IT analytics. Here's how they relate to quantum computing.
A graph is a collection of points, called vertices, and lines between those points, are called edges. Graphs are used in mathematics, engineering and computer science, and they are growing as a technology in IT analytics.
"Graphs can be much more flexible than other [artificial intelligence] techniques, especially when it comes to adding new sources of data," said Steve Reinhardt, VP of product development at Quantum Computing Inc., which produces quantum computing software that operates on graphs. "For instance, if I'm storing patient data and I want to add a dimension to track the unlikely event of testing positive for coronavirus after being vaccinated, graphs only consume storage proportional to the number of patients encountering the rare event."
SEE: The CIO's guide to quantum computing (free PDF) (TechRepublic)
Graphs can be heady stuff, so let's break that down.
A database software, such as SQL or NoSQL, would be a logical technology to use if you want to plot the many different relationships between data. Analytics programs then operate on this data and how it is interrelated to derive insights that answer a specific business query.
Unfortunately, to process all of the data relationships in Reinhardt's patient example, a relational database must go through all patient records and store them in order to identify that subset of patients who tested positive for the coronavirus after being vaccinated. For an average hospital, this processing could involve hundreds of thousands of patient records and all of their multiple relationships to the coronavirus and the vaccine.
Now let's put that same problem into a graph. The graph uses data points, lines connecting those points and vertices which show where the lines intersect because they have a common shared context. This shared context enables the graph to identify a subset of patients who tested positive for COVID-19 after they had a vaccine and only store that subset of data for processing. Because a graph can intelligently identify a subset of data through its relationships before data gets processed, processing time is saved.
SEE: Big data graphs are playing an important role in the coronavirus pandemic (TechRepublic)
As IT expands into more data sources for its analytics and data stores, processing will grow more complex and cumbersome. This is where a combination of graphs and quantum computing will one day be able to process data faster than traditional methods.
"Graphs have a rich set of well-understood techniques for analyzing them," Reinhardt said. "Some of these are well-known from analyzing graphs that occur naturally, such as the PageRank algorithm that Google originally used to gauge the importance of web pages, and the identification of influencers in social networks. This is why we are focused on making these algorithms more practically usable."
That sounds good to IT, where there is an issue of understanding enough about graphs and quantum computing to put them to use.
SEE: Research: Quantum computing will impact the enterprise, despite being misunderstood (TechRepublic)
"The goal is to develop solutions so users need to know nothing about the details of quantum computers, including low-level architectural features such as qubits, gates, circuits, couplers and QUBOs," Reinhardt said. "Today, quantum processors are almost never faster than the best classical methods for real-world problems, so early users need to have appropriate expectations. That said, the performance of quantum processors has been growing dramatically, and the achievement of quantum advantage, superior quantum performance on a real-world problem, may not be far off, so organizations that depend on a computing advantage will want to be prepared for that event."
And that is the central point: While graphs and quantum computing are still nebulous concepts to many IT professionals, it isn't too early to start placing them on IT roadmaps, since they will certainly play roles in future analytics.
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April 9, 2021 Quantum Delta NL, a research programme in which Leiden University participates, has been awarded 615 million euros from the National Growth Fund to help develop the Netherlands into a top player in quantum technology. This has been announced at the presentation of the honoured proposals in The Hague.
Quantum Delta NL is a cooperation of companies and research institutes in which the research has been organised in five hubs at the universities of Delft, Leiden, Amsterdam, Twente and Eindhoven.
The research groupApplied Quantum Algorithms (aQa)at the Leiden institutes for physics and computer science develops quantum algorithms for chemical and material science applications, in cooperation with Google, Shell, Volkswagen and Total.
Research into quantum computing has been going on for twenty years, bringing real world application ever closer, says Carlo Beenakker, professor in Theoretical Physics and Deputy Chair of Quantum Delta NL. I seegreat enthusiasm in my students to apply abstract concepts from quantum physics to the solution of practical problems. This is the revolutionary technology of their generation.
The goal of aQa is to make quantum algorithms practically applicable, pertaining to questions ofsocietal and economical relevance. We cooperate narrowly with our industrial partners to render these large investments as useful as possible, says computer science researcher Vedran Dunjko. Recently, he published in the journal Natureabout artificial intelligence implemented through quantum computers.
Quantum Delta NLs ambition is to position the Netherlands as a Silicon Valley for quantum technology in Europe during the coming seven years. The programme provides for the further development of the quantum computer and the quantum internet, which will be open for end users in business and societal sectors, including education.
It aims for a flourishing ecosystem where talent is fostered at all levels, and where cooperation happens over institutional borders to develop a new European high-tech industry.
Source: Leiden University
Today, our life is so different in comparison to the end of the 20th century. Gone are the days when our mobile phones had small screens, keyboard mounted on the body and was limited to just making calls and messages. Today, we are at a stage where mobile phones are way more powerful than desktop computers. With the advent of technology, we are now all set to embark on a journey to build the next-generation computer. This is exactly where the concept of quantum computers comes into play.
The main idea behind this is to solve problems that classical computing could not. Not one, not two but there seems to be many areas where classical computing seems to have not worked in our favour. Though, we do have some quantum computers in place, they are still unreliable as far as the demands are concerned. Today, we get to see giant market players like IBM, Google, Microsoft, etc. in the race of building the first powerful quantum computer. Though this is an expensive invention, companies are not hesitating from pouring in so much money because they know that the advantages offered last an eternity. Today, the aim is to build a quantum communication system that doesnt communicate bits and bytes, but quantum states that quantum computers can understand. The reason why this is important is because we are in a position to build up a quantum version of the internet.
Quantum AI, in addition to being smart and fast also boasts of an advantage of superposition. Considering the fact that classical AI works in a black box, Quantum AI stands the potential to exploit superposition to operate in many black boxes at once.
That said, how about being prepared for a World War 3 well in advance? It is highly likely that the US takes up every possible step to pre-emptively win World War 3 and before the perceived enemy nations could even react.
As known to all, today the computers employ binary logic to address the yes-or-no questions. But with quantum computers, the scenario will be a lot different. They wouldnt be limited to just yes-or-no questions. Theyll hold the potential to determine the confidence factor for a given operation. A lot is being speculated about the first huge powerful quantum computer that is soon going to make its entry into the world of technology.
One of the researchers at the Fermi National Accelerator Laboratory, a Department of Energy research lab for the US government,Prasanth Shyamsundar described two new types of algorithms that could revolutionize quantum computing. Well, not just this. These algorithms can lead to a quantum brain for military AI systems as well.
He talked about how one of the two algorithms allows the same AI to sort through the entire stack of albums at the same time. The second algorithm can assess how jazzy the stack is as a whole. This algorithm would allow the scientists to estimate the average rating of all the records. In a nutshell, both these algorithms allow for a range of outputs to more accurately characterize information with a quantum speedup contrary to what classical computing methods do. Prasanth Shyamsundars paper represents the groundwork towards basic functioning quantum algorithms.
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The World Awaits the First Powerful Quantum Computer - Analytics Insight
Quantum computers, like one coming to Cleveland Clinic, can help create medical breakthroughs but still are i – cleveland.com
CLEVELAND, Ohio Quantum computers able to handle huge amounts of data are the technology of the future. Researchers think they will be able to do very important things, but it takes more than a visit from the Geek Squad to get them set up and ready to be useful.
The Cleveland Clinic, which is getting a quantum computer next year through a new 10-year partnership with IBM, says it will use the computer to speed up medical research.
But there are questions about what quantum computers can do, how to turn current real-world data into formats they can use, and which problems are best for quantum and which are best for classical computers.
Quantum, from our perspective, is the technology of tomorrow, said Dr. Lara Jehi, chief research information officer at the Clinic. Unless we try to create this, we will always be stuck with the limitations that we have now in biomedical research and health care.
The quantum computer, called the IBM Quantum System One, will be installed at the Clinic in early 2022. A few years later, IBM will deliver an upgraded quantum system.
The joint Clinic-IBM center, called the Discovery Accelerator, will feature artificial intelligence, hybrid cloud data storage and quantum computing technologies. A hybrid cloud is a data storage technology that allows for faster storage and analysis of large amounts of data.
The Discovery Accelerator will be part of the Clinics Center for Global and Emerging Pathogens Research, where advanced technology from IBM will assist research into genomics, population health, clinical applications, and chemical and drug discovery.
Heres a closer look at where the field of quantum computing is now, and how it could influence health care in the future.
Quantum vs. classical computing
Quantum computing is based on quantum phenomenon, not ones and zeros, said Anthony Annunziata, director of the IBM Quantum Network. It will be able to crunch larger amounts of data at speeds that regular computers cant match.
Quantum computers are able to explore multiple solutions at the same time, emphasize solutions that look promising and de-emphasize ones that are less promising, said Jacob Taylor, a Fellow in the Joint Center for Quantum Information and Computer Science at the University of Maryland.
Quantum computers differ from everyday laptops and mainframes because they use quantum bits, or qubits, to perform functions. While everyday computers use 0 and 1 to represent information, qubits can be both zeros and ones at the same time.
This allows quantum computers to crunch large amounts of data in parallel that classical computers have to do sequentially. Quantum scientists have been working to make quantum computing a reality and show it can perform tasks in a fraction of the time it takes classical computers.
Is quantum computing reality or theory?
Quantum computing holds great promise to accelerate many applications, but were still very much in the phase of inventing and developing how that works, Annunziata said.
It is coming. It is coming fast. It is not yet at the state today where you can solve full-scale problems, Annunziata said. But it is definitely more than theory. It is a real technology.
The field of quantum computers is in an exploration phase, and Taylor expects that during this time, researchers will find that its easier to solve a problem in a new way with a classical computer than with a quantum computer.
Its not a net positive, because what happens in the process is, we discover new classical algorithms that will outperform what we already had, Taylor said. So we end up transforming health care -- not only because the quantum computers run the solution, but because you have a better classical solution you were forced to find in order to understand when the quantum system wasnt that helpful.
However, Taylor cautioned, It is my expectation that almost none of the proposed applications are going to change health care outcomes as we know it.
Quantum computers could advance new drugs, cancer treatments
Quantum computing could help find new molecules that are possible candidates for drugs, Annunziata said. Alongside running tests in the lab, the goal is to accurately simulate new drugs on quantum computers.
Taylor agreed that chemistry may be a promising area for quantum computers.
Weve had some successes in using quantum chemistry techniques that typically run on classical computers, and also using some machine learning techniques to complement those. Taylor said. You can test many different possible solutions against your target molecule, which is a lot of what drug discovery is about -- trying to find out what reacts with what. So I do have some hope there.
Quantum computers could help sequence genes in cancer cells quickly, leading to more targeted treatment, Jehi said. In that area, role of AI and bioinformatics and eventually quantum, if it ends up panning out in that space, would have a big impact, she said.
The ability to make quantum computers helpful hinges on the ability to load data into it, and that is very challenging, Taylor said.
Quantum computers work best with quantum data. Most data from the real world such as patient information records or data from Fitbits worn by every American adult isnt in a form that quantum computers can use, he said.
Researchers will use advances in machine learning and artificial intelligence to transform real-world data into a form that quantum computers can use, Taylor said.
How soon will patients see results from the quantum computer?
Thats hard to say, but Jehi said the Clinic has current research projects involving genomics, artificial intelligence and big data that could benefit from the technology that the partnership with IBM will bring to the hospital system.
IBM, Cleveland Clinic Team Up on Quantum Computing and a Healthcare Discovery Accelerator – Morning Brew
In The Office, Ryan Howard bets on Ohios future as the next Silicon Valley: They call it the Silicon Prairie.
It looks like IBMs been binge-watching in quarantine, too: The company just announced a 10-year partnership with the Cleveland Clinic, a nonprofit academic medical center, centered on AI, quantum, and cloud computing.
Heres the plan: Establish the Discovery Accelerator, a research engine using emerging tech to advance healthcare and life sciences. Think: discovering new molecules and expanding knowledge on viral pathogens, treatments, and more.
That engine will be powered, in part, by a quantum computer. IBM plans to release the Q System One in 2023, and the Cleveland Clinic will be the first private-sector organization to buy and operate its own IBM quantum computer. (Right now, they can only be found in the companys own labs and data centers.)
Big picture: Cleveland Clinic gets access to pioneering healthcare research tech, and IBM gets its first major quantum computer sale...and a whole lot of exposure in the healthcare sector. The latter likely tops IBMs pros list after the disappointments of Watson, which made headlines for under-delivering in healthcare AI.
Probabilistic computing is one of the excellent ways to deal with the uncertainties in the data
Over the years, the world of technology has been waiting desperately for quantum computing. The fact that still remains is that quantum computers sound great as far as theory is concerned. But building practical machines is concerned with a truck load of hurdles and challenges. On the brighter side, if the engineers are able to successfully step into the world of practical quantum computers, the kind of computations performed would be taken to a different level altogether. Considering these challenges, one of the most remarkable ways that we could employ here is Probabilistic computing. It is one of the excellent ways to deal with the uncertainties in the data.
Experts believe that the technical challenges faced in case of quantum computers are so immense that it is very unlikely that general-purpose quantum computers would become available anytime in the future. Additionally, it might take anywhere between 5 to 10 years or may be even more to bring the first practical general-purpose quantum computers on line. Evidently, it is a huge investment of time. It is because of all the complications and challenges that people are inspired to delve deeper into understanding the importance and role of probability in computing systems. Late physicist Richard Feynman was confident about people accepting this and proceeding with the same about 30 years back. He believed that a probabilistic computer holds the potential to stand as a competition to quantum computers.
The base, needless to say, is a probabilistic bit. Long back, computers used a magnet with two possible directions of magnetization to store a bit. These magnets can be used to implement p-bits. A team had used the similar technique to build a probabilistic computer in 2019 with eight p-bits.
The best part about using unstable magnets as the fundamental building block is that the p-bit can be implemented using a few transistors rather than thousands of them. This feature makes it possible to build larger probabilistic computers.
Talking about the working principle of probabilistic computers, a system of p-bits evolves from an initial to a final state. Obviously, there are could be a considerable number of intermediate states. Each path has a different probability. The surprise element here is that which path is taken by the computer totally depends on the chance. To get the overall probability, you need to add together all the probabilities of all possible paths. In case of a quantum computer, it uses qubits instead of p-bits. Here, the probability is determined by adding the complex amplitudes for all the possible paths between the initial state and the final state.
Simply put, the difference between a probabilistic computer and a quantum computer is that the former adds up the probabilities whereas the latter adds complex probability amplitudes. There is yet another point to note, probabilities are positive numbers less than one whereas the probability amplitudes are complex numbers. Hence, when you add an additional path in case of quantum computing, it can cancel out an existing path. On the other hand, adding an extra path in probabilistic computers can only increase the final probability.
Another point worth noting is that the qubits carry complex amplitudes. These have to be carefully protected from the environment. A lot of attention has to be paid to the temperature thats maintained. All this hassle is eliminated in case of a probabilistic computer as it can be built with simpler technology operating at room temperature.
On the downside, you cannot deal with negative probabilities here. Thisfurther makes it suitable only for those algorithms that do not require path cancellation.
In a nutshell, probabilistic computing is one of the most effective ways to replace quantum computing.
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QCI Expands Sales and Marketing Team to Accelerate Growth and Advance Enterprise Adoption of Quantum Computing – GlobeNewswire
LEESBURG, Va., April 06, 2021 (GLOBE NEWSWIRE) -- Quantum Computing Inc. (OTCQB: QUBT) (QCI), a leader in bridging the power of classical and quantum computing, has expanded its executive team with sales and marketing leaders that position the company for immediate and long-term growth. QCI named iconic tech sales leader, Dave Morris, as its chief revenue officer, and tech marketing veteran Rebel Brown as vice president of marketing. With these hires, the company plans to accelerate the integration of quantum into enterprise problem solving, an effort thats already well underway.
It is extremely validating for QCIs business model to attract such accomplished professionals leading our sales and marketing efforts, said Robert Liscouski, CEO of QCI. Both bring a wealth of experience with the worlds largest computing companies and most exciting startups. The combination makes them so incredibly powerful for our efforts. Equally significant, both Dave and Rebel have broken ground in new areas of software and emerging technologies like QCI is doing in quantum. We are confident that the expanded team will accelerate our growth and advance quantum computing in the enterprise ahead of industry predictions.
Dave Morris has over 20 years of success leading regional, national, and international sales strategy, business development and execution, including significant roles with Cisco Systems and Intel. He previously was chief revenue officer of Airspace Systems, Inc., a leader in the drone detection and analytics space. Dave has a proven ability to set a clear vision and deliver meaningful results. He has prepared and adapted large sales teams to drive change and exploit technology evolution, both critical elements in quantum computing.
I am excited to join a team of accomplished professionals who are blazing the path to bring real value to the business community through QCIs ready-to-run quantum software, explained Morris. I am honored to be QCIs face to the business community at this pivotal inflection in the evolution of quantum computing. It is a rare opportunity to change computing at a fundamental level and apply it to real-word business problems. I look forward to working with progressive businesses who appreciate the potential of quantum to drive competitive advantage and boost results.
Rebel Brown has helped myriad U.S. and European advanced tech companies create, enter and lead markets.She brings deep expertise in strategy, product marketing/management and positioning. Rebel has helped raise more than $500M in startup funding, launched innovative technologies in software systems, development and HPC, and supported successful exits to companies like Apple, IBM, EMC, SGI and BEA. Along the way, Rebel helped introduce Unix to the commercial marketplace, launched the first open systems management platforms and put C++ objects on the map.
Ive successfully launched some of the most advanced tech throughout my career and have never seen a shift as potentially impactful as quantum computing, said Rebel Brown. QCI has quickly established itself as the market leader in ready-to-run quantum software. Like any early market, the hardest part can be separating hype from reality. I am excited to join the QCI team because of the companys commitment to demystifying the technology, and bringing the power of quantum to all users, not just quantum scientists, through real-world solutions that improve business results today.
QCIs flagship quantum software, Qatalyst, puts the power of quantum techniques for classical computing into the hands of non-quantum experts for solving critical business problems today. Qatalyst is the first to drive computational results on any quantum or classical computer without any new programming or low-level coding, quantum experts or exorbitantly long and costly development cycles. Qatalyst is now commercially available to support the QikStart Program, QCIs initiative to accelerate the real-world use cases for quantum computing.
QCI is unique in its capability to access a variety of quantum computers, including D-Wave, IonQ, and Rigetti, through Amazons Braket.
To learn more about QCI and how Qatalyst can deliver results for your business today, go to http://www.quantumcomputinginc.com.
About Quantum Computing Inc.Quantum Computing Inc. (OTCQB: QUBT) (QCI) is focused on accelerating the value of quantum computing for real-world business solutions. The companys flagship product, Qatalyst, is the first software to bridge the power of classical and quantum computing, hiding complexity and empowering SMEs to solve complex computational problems today. QCIs expert team in finance, computing, security, mathematics and physics has over a century of experience with complex technologies; from leading edge supercomputing innovations, to massively parallel programming, to the security that protects nations. Connect with QCI on LinkedIn and @QciQuantum on Twitter. For more information about QCI, visit http://www.quantumcomputinginc.com.
Important Cautions Regarding Forward-Looking StatementsThis press release contains forward-looking statements as defined within Section 27A of the Securities Act of 1933, as amended, and Section 21E of the Securities Exchange Act of 1934, as amended. By their nature, forward-looking statements and forecasts involve risks and uncertainties because they relate to events and depend on circumstances that will occur in the near future. Those statements include statements regarding the intent, belief or current expectations of Quantum Computing (Company), and members of its management as well as the assumptions on which such statements are based. Prospective investors are cautioned that any such forward-looking statements are not guarantees of future performance and involve risks and uncertainties, and that actual results may differ materially from those contemplated by such forward-looking statements.
The Company undertakes no obligation to update or revise forward-looking statements to reflect changed conditions. Statements in this press release that are not descriptions of historical facts are forward-looking statements relating to future events, and as such all forward-looking statements are made pursuant to the Securities Litigation Reform Act of 1995. Statements may contain certain forward-looking statements pertaining to future anticipated or projected plans, performance and developments, as well as other statements relating to future operations and results. Any statements in this press release that are not statements of historical fact may be considered to be forward-looking statements. Words such as "may," "will," "expect," "believe," "anticipate," "estimate," "intends," "goal," "objective," "seek," "attempt," aim to, or variations of these or similar words, identify forward-looking statements. These risks and uncertainties include, but are not limited to, those described in Item 1A in the Companys Annual Report on Form 10-K, which is expressly incorporated herein by reference, and other factors as may periodically be described in the Companys filings with the SEC.
Qatalyst and QikStart are trademarks of Quantum Computing Inc. All other trademarks are the property of their respective owners.
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The technology harnesses quantum physics to perform calculations faster than ever
The IBM Q System One quantum computer at IBM's research facility in New York
Misha Friedman/Getty Images
By Donna Lu
Quantum computers are machines that use the properties of quantum physics to store data and perform computations. This can be extremely advantageous for certain tasks where they could vastly outperform even our best supercomputers.
Classical computers, which include smartphones and laptops, encode information in binary bits that can either be 0s or 1s. In a quantum computer, the basic unit of memory is a quantum bit or qubit.
Qubits are made using physical systems, such as the spin of an electron or the orientation of a photon. These systems can be in many different arrangements all at once, a property known as quantum superposition. Qubits can also be inextricably linked together using a phenomenon called quantum entanglement. The result is that a series of qubits can represent different things simultaneously.
For instance, eight bits is enough for a classical computer to represent any number between 0 and 255. But eight qubits is enough for a quantum computer to represent every number between 0 and 255 at the same time. A few hundred entangled qubits would be enough to represent more numbers than there are atoms in the universe.
This is where quantum computers get their edge over classical ones. In situations where there are a large number of possible combinations, quantum computers can consider them simultaneously. Examples include trying to find the prime factors of a very large number or the best route between two places.
However, there may also be plenty of situations where classical computers will still outperform quantum ones. So the computers of the future may be a combination of both these types.
For now, quantum computers are highly sensitive: heat, electromagnetic fields and collisions with air molecules can cause a qubit to lose its quantum properties. This process, known as quantum decoherence, causes the system to crash, and it happens more quickly the more particles that are involved.
Quantum computers need to protect qubits from external interference, either by physically isolating them, keeping them cool or zapping them with carefully controlled pulses of energy. Additional qubits are needed to correct for errors that creep into the system.
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What is a quantum computer? | New Scientist
Google claims it has designed a machine that needs only 200 seconds to solve a problem that would take the worlds fastest supercomputer 10,000 years to figure out.
The speed achieved by the computer represents a breakthrough called quantum supremacy, according to a blog post from the company and an accompanying article in the scientific journal Nature.
The results announced Wednesday herald the rise of quantum computers, which can store and process much more information than their classical cousins by tapping into the powerful forces contained in the field of physics known as quantum mechanics.
One big difference: Normal computers use data that exist in only one state at a time a one, or a zero. Quantum computers use quantum bits, or qubits, which can simultaneously be any combination of zero and one. The difference means much faster processing speeds.
Google (GOOGL) will now try to build a fault-tolerant quantum computer as quickly as possible. The company sees applications in designing lightweight batteries for cars and airplanes, as well as new medicines.
Achieving the necessary computational capabilities will still require years of hard engineering and scientific work. But we see a path clearly now, and were eager to move ahead, it said in the post.
Google CEO Sundar Pichai with the company's quantum computer.
The speed experiment devised by Google was criticized by some experts and rival companies after the results leaked online ahead of their official publication date.
IBM (IBM) said in a blog post Monday that Google had overestimated the difficulty of the computing task. Instead of 10,000 years, IBM (IBM) argued the problem could be solved by a classical computer in just 2.5 days.
We urge the community to treat claims that, for the first time, a quantum computer did something that a classical computer cannot with a large dose of skepticism, IBM said.
Google CEO Sundar Pichai defended the companys claim in an interview with MIT Technology Review published Wednesday, comparing it to the Wright brothers attempts at flight.
The first plane flew only for 12 seconds, and so there is no practical application of that, said Pichai. But it showed the possibility that a plane could fly.
China is considered a leader in the development of quantum computing, which could have significant military applications. The United States is trying to catch up, sparking fears of a quantum arms race.
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Quantum supremacy: Google says its computer did a 10,000 ...
"IEEE is now at the center of a global conversation to understand the power and promise of quantum computing." Travis Humble, Oak Ridge National Lab
IEEE Quantum Weekis recognized as a leading venue for presenting high-quality original research, ground-breaking innovations, and insights in quantum computing and engineering. Throughparticipation from the international quantum community,QCE21 offers an extensive conference program withworld-class keynote speakers, technical paper presentations,innovative posters, excitingexhibits, technical briefings, workforce-building tutorials, community-building workshops,stimulating panels,and Birds-of-Feather sessions.
Stay informed of all QCE21 updates - sign up for QCE21 conference alerts.
Participation opportunities are available for a limited time. Authorsare invited to submit contributionsfor technical papers, tutorials, workshops, panels, posters, and Birds-of-a-Feather sessions. Papers accepted by QCE21 will be submitted to the IEEE Xplore Digital Library, and the best papers will be invited to the journalsIEEE Transactions on Quantum Engineering (TQE)andACM Transactions on Quantum Computing (TQC). The submission schedule is available at QCE21 Submission Deadlines.
The high standards for QCE21 were set by the tremendous success of the inaugural QCE20.Over 800 people from 45 countries and 225 companies attended the premier event that delivered 270+ hours of programming on quantum computing and engineering.
The second annual Quantum Week will virtually connect a wide range of leading quantum professionals, researchers, educators, entrepreneurs, champions and enthusiasts to exchange and share their experiences, challenges, research results, innovations, applications, and enthusiasm, on all aspects of quantum computing, engineering and technologies. The IEEE Quantum Week schedule will take place during Mountain Daylight Time (MDT).
Visit IEEE QCE21for all event news including sponsorship and exhibitor opportunities.
QCE 21 is co-sponsored by the IEEE Computer Society, IEEE Communications Society, IEEE Council of Superconductivity, IEEE Future Directions Committee, and IEEE Photonics Society.
About the IEEE Computer Society
The IEEE Computer Societyis the world's home for computer science, engineering, and technology. A global leader in providing access to computer science research, analysis, and information, the IEEE Computer Society offers a comprehensive array of unmatched products, services, and opportunities for individuals at all stages of their professional career. Known as the premier organization that empowers the people who drive technology, the IEEE Computer Society offers international conferences, peer-reviewed publications, a unique digital library, and training programs.
About the IEEE Communications Society
TheIEEE Communications Societypromotes technological innovation and fosters creation and sharing of information among the global technical community. The Society provides services to members for their technical and professional advancement and forums for technical exchanges among professionals in academia, industry, and public institutions.
About the IEEE Council on Superconductivity
TheIEEE Council on Superconductivityand its activities and programs cover the science and technology of superconductors and their applications, including materials and their applications for electronics, magnetics, and power systems, where the superconductor properties are central to the application.
About the IEEE Future Directions Quantum Initiative
IEEE Quantumis an IEEE Future Directions initiative launched in 2019 that serves as IEEE's leading community for all projects and activities on quantum technologies. IEEE Quantum is supported by leadership and representation across IEEE Societies and OUs. The initiative addresses the current landscape of quantum technologies, identifies challenges and opportunities, leverages and collaborates with existing initiatives, and engages the quantum community at large.
About the IEEE Photonics Society
TheIEEE Photonics Societyforms the hub of a vibrant technical community of more than 100,000 professionals dedicated to transforming breakthroughs in quantum physics into the devices, systems, and products to revolutionize our daily lives. From ubiquitous and inexpensive global communications via fiber optics, to lasers for medical and other applications, to flat-screen displays, to photovoltaic devices for solar energy, to LEDs for energy-efficient illumination, there are myriad examples of the Society's impact on the world around us.
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Quantum Week 2021 Unveils the Latest in Quantum Computing and Engineering - PRNewswire