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The announcement of the agreement was made during CES 2020, the annual global technology conference and showcase in Las Vegas.

Together with the Air Force Research Lab (AFRL) and IBM, NYU will explore quantum computing research to study measurement-based quantum computing, materials discovery with variational quantum eigensolver, and emulating new phases on small quantum systems.

We are excited to join AFRL and IBM to transform quantum computing concepts into a powerful technology by educating a new quantum workforce, expanding our scientific partnership and engaging in cross disciplinary collaboration, said Javad Shabani, an assistant professor of physics at NYU.

Under the agreement to join the AFRL hub, NYU will be part of a community of Fortune 500 companies, startups, academic institutions, and research labs working to advance quantum computing and explore practical applications. NYU will leverage IBMs quantum expertise and resources, Qiskit software and developer tools, and will have cloud-based access to IBMs Quantum Computation Center. IBM offers, through the cloud, 15 of the most advanced universal quantum computing systems available, including a 53-qubit qubit systemthe largest commercially available system in the industry.

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New York University Partners with IBM to Explore Quantum Computing for Simulation of Quantum Systems and Advancing Quantum Education - Quantaneo, the...

Way back in the 1960s, Gordon Moore, the co-founder of Intel, observed that the number of transistors that could be fitted on a silicon chip was doubling every two years. Since the transistor count is related to processing power, that meant that computing power was effectively doubling every two years. Thus was born Moores law, which for most people working in the computer industry or at any rate those younger than 40 has provided the kind of bedrock certainty that Newtons laws of motion did for mechanical engineers.

There is, however, one difference. Moores law is just a statement of an empirical correlation observed over a particular period in history and we are reaching the limits of its application. In 2010, Moore himself predicted that the laws of physics would call a halt to the exponential increases. In terms of size of transistor, he said, you can see that were approaching the size of atoms, which is a fundamental barrier, but itll be two or three generations before we get that far but thats as far out as weve ever been able to see. We have another 10 to 20 years before we reach a fundamental limit.

Weve now reached 2020 and so the certainty that we will always have sufficiently powerful computing hardware for our expanding needs is beginning to look complacent. Since this has been obvious for decades to those in the business, theres been lots of research into ingenious ways of packing more computing power into machines, for example using multi-core architectures in which a CPU has two or more separate processing units called cores in the hope of postponing the awful day when the silicon chip finally runs out of road. (The new Apple Mac Pro, for example, is powered by a 28-core Intel Xeon processor.) And of course there is also a good deal of frenzied research into quantum computing, which could, in principle, be an epochal development.

But computing involves a combination of hardware and software and one of the predictable consequences of Moores law is that it made programmers lazier. Writing software is a craft and some people are better at it than others. They write code that is more elegant and, more importantly, leaner, so that it executes faster. In the early days, when the hardware was relatively primitive, craftsmanship really mattered. When Bill Gates was a lad, for example, he wrote a Basic interpreter for one of the earliest microcomputers, the TRS-80. Because the machine had only a tiny read-only memory, Gates had to fit it into just 16 kilobytes. He wrote it in assembly language to increase efficiency and save space; theres a legend that for years afterwards he could recite the entire program by heart.

There are thousands of stories like this from the early days of computing. But as Moores law took hold, the need to write lean, parsimonious code gradually disappeared and incentives changed. Programming became industrialised as software engineering. The construction of sprawling software ecosystems such as operating systems and commercial applications required large teams of developers; these then spawned associated bureaucracies of project managers and executives. Large software projects morphed into the kind of death march memorably chronicled in Fred Brookss celebrated book, The Mythical Man-Month, which was published in 1975 and has never been out of print, for the very good reason that its still relevant. And in the process, software became bloated and often inefficient.

But this didnt matter because the hardware was always delivering the computing power that concealed the bloatware problem. Conscientious programmers were often infuriated by this. The only consequence of the powerful hardware I see, wrote one, is that programmers write more and more bloated software on it. They become lazier, because the hardware is fast they do not try to learn algorithms nor to optimise their code this is crazy!

It is. In a lecture in 1997, Nathan Myhrvold, who was once Bill Gatess chief technology officer, set out his Four Laws of Software. 1: software is like a gas it expands to fill its container. 2: software grows until it is limited by Moores law. 3: software growth makes Moores law possible people buy new hardware because the software requires it. And, finally, 4: software is only limited by human ambition and expectation.

As Moores law reaches the end of its dominion, Myhrvolds laws suggest that we basically have only two options. Either we moderate our ambitions or we go back to writing leaner, more efficient code. In other words, back to the future.

What just happened?Writer and researcher Dan Wang has a remarkable review of the year in technology on his blog, including an informed, detached perspective on the prospects for Chinese domination of new tech.

Algorithm says noTheres a provocative essay by Cory Doctorow on the LA Review of Books blog on the innate conservatism of machine-learning.

Fall of the big beastsHow to lose a monopoly: Microsoft, IBM and antitrust is a terrific long-view essay about company survival and change by Benedict Evans on his blog.

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Were approaching the limits of computer power we need new programmers now - The Guardian

The Global Quantum Computing Technologies Market has witnessed continuous growth in the past few years and is projected to grow even further during the forecast period (2020-2025). The assessment provides a 360 view and insights, outlining the key outcomes of the industry. These insights help the business decision-makers to formulate better business plans and make informed decisions for improved profitability. In addition, the study helps venture capitalists in understanding the companies better and make informed decisions. Some of the key players in the Global Quantum Computing Technologies market are Airbus Group, Cambridge Quantum Computing, IBM, Google Quantum AI Lab, Microsoft Quantum Architectures, Nokia Bell Labs, Alibaba Group Holding Limited, Intel Corporation & Toshiba

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Quantum Computing Technologies Market to Witness Huge Growth by 2020-2025, Latest study reveals - ReportsPioneer

It is eagerly awaited! The "Forteza" report, named after its rapporteur, Paula Forteza, Member of Parliament for La Rpublique en Marche (political party of actual President Emmanuel Macron), should finally be officially revealed on January 9th. The three rapporteurs are Paula Forteza, Member of Parliament for French Latin America and the Caribbean, Jean-Paul Herteman, former CEO of Safran, and Iordanis Kerenidis, researcher at the CNRS. Announced last April, this report was initially due at the end of August, then in November, then... No doubt the complex agenda, between the social movements in France, and the active participation of the MP in the Parisian election campaign of Cdric Villani, mathematician and dissident of La Rpublique en Marche... had to be shaken up. In any case, it is thus finally on January 9th that this report entitled "Quantum: the technological shift that France will not miss", will be unveiled.

"Entrusted by the Prime Minister in April 2019, the mission on quantum technologies ends with the submission of the report by the three rapporteurs Paula Forteza, Jean-Paul Herteman, and Iordanis Kerenidis. Fifty proposals and recommendations are thus detailed in order to strengthen France's role and international position on these complex but highly strategic technologies. The in-depth work carried out over the last few months, fueled by numerous consultations with scientific experts in the field, has led the rapporteurs to the conclusion that France's success in this field will be achieved by making quantum technologies more accessible and more attractive. This is one of the sine qua non conditions for the success of the French strategy", explains the French National Congress in the invitation to the official presentation ceremony of the report.

The presentation, by the three rapporteurs, will be made in the presence of the ministers for the army, the economy and finance, and higher education and research. The presence of the Minister of the Armed Forces, as well as the co-signature of the report by the former president of Safran, already indicates that military applications will be one of the main areas of proposals, and possibly of funding. Just as is the case in the United States, China or Russia.

Of course, the report will go into detail about the role of research, and of the CNRS, in advances in quantum computing and communication. Of course, the excellent work of French researchers, in collaboration with their European peers, will be highlighted. And of course, France's excellence in these fields will be explained. France is a pioneer in this field, but the important questions are precisely what the next steps will be. The National Congress indicates that this report will present 50 "proposals and recommendations". Are we to conclude that it will be just a list of proposals? Or will we know how to move from advice to action?

These are our pending questions:

- The United States is announcing an investment of USD 1.2 billion, China perhaps USD 10 billion, Great Britain about 1 billion euros, while Amazon's R&D budget alone is USD 18 billion... how can a country like France position itself regarding the scale of these investments? To sum up, is the amount of funds allocated to this research and development in line with the ambitions?

- Mastering quantum technologies are becoming a geopolitical issue between the United States and China. Should Europe master its own technologies so as not to depend on these two major powers? On the other hand, is this not the return of a quantum "Plan calcul from the 60s? How can we avoid repeating the same mistakes?

- Cecilia Bonefeld-Dahl, Managing Director of DigitalEurope recently wrote that Europe risks being deprived of the use of quantum technologies if it does not develop them itself. Christophe Jurzcak, the head of Quantonation, stated that it is not certain that France will have access to quantum technologies if it does not develop them itself. Is this realistic? Do we have the ressources?

- French companies currently invest very little in research in the field of quantum computing. With the exception of Airbus, the main feedback that we know of is in Canada, Australia, Spain, Germany, etc. Should we also help companies to embrace these technologies, or should we only finance research and development on the part of universities and business creators? Is there a support component for companies? So that technologies are not simply developed in France and sold elsewhere, but that France is the leading market for local developments.

See you on January 9th on Decideo for more details and our objective analysis of the content of this document.

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January 9th: France will unveil its quantum strategy. What can we expect from this report? - Quantaneo, the Quantum Computing Source

Tech giant Google announced a few days ago that it had reached Quantum Supremacy. Now, another tech heavyweight IBM, is announcing its lofty quantum ambitions that could be detrimental to cryptocurrencies.

At the CES 2020 conference yesterday, IBM announced that it is using its 28-qubit quantum computer called Raleigh to achieve a Quantum Volume of 32. While it is not a very significant number as far as breaking the crypto code is concerned, it is important to note that IBM is doubling its volume every year.

Quantum Volume is a number used to describe the level of complexity of problems that a quantum computer can solve. A higher Quantum Volume means a more powerful computer. While the world keeps talking about AI, cryptocurrencies, blockchain, IoT and other emerging technologies, it is quantum computing that could become the most important innovation of this century. It has the ability to touch almost every industry and walk of life and can impact other emerging technologies significantly.

The first of practical quantum computers were introduced by Jonathan Home in 2009, but since then, tech giants like IBM and Google have taken the lead to create the next generation of powerful computing systems. For long, Bitcoin has been considered vulnerable to the attack of quantum computers. Therefore, Google and IBMs developments could pose a significant threat to the existence of the crypto sector.

Authors of a June 2017 paper on cryptography suggest that a quantum computer with the processing power of 2,500 qubits will be powerful enough to break the 256-bit encryption used on the Bitcoin blockchain. The most powerful quantum computer today holds only a fraction of that processing power, i.e. 72-qubit.

Crypto godfather David Chaum has already started warning the community to brace for impact and start working on an answer to Google and IBMs quantum powers right now. While their processing powers look inconsequential right now, the day may not be far when they can actually start creating ripples in the crypto community.

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IBM Becomes the Next Big Threat to Crypto after Google - CryptoVibes