Category Archives: Quantum Computing

Global investors were bracing for a rough earnings season, but most companies have so far surpassed much-lowered analyst expectations.

Refinitiv data showed that about 60 per cent of the biggest European listed companies have, so far, beaten dramatically lowered estimates.

On Wall Street, about 82 per cent of S&P 500 companies reporting so far have beaten estimates.

Meanwhile, the Australian reporting season continues today with large cap rail company Aurizon Holdings and real estate giant GPT Group both of which nudged higher in early trade.

The ASX more generally is in positive territory, with the benchmark ASX 200 Index up 0.85 per cent to 6,055 points by 11:30am AEST.

Here are the best performing ASX small cap stocks at 12pm Monday August 10:

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Biotech Emerald Clinics (ASX:EMD) jumped +70 per cent after signing a contract with the UK arm of pot giant Canopy Growth.

Secos Group (ASX:SES) locked in a significant supply contract for its compostable pet waste bags with a leading US pet supply company.

The stock was up +25 per cent in morning trade.

And quantum computing stock Archer Materials (ASX:AXE) is progressing through milestones as it aims to build a room-temperature quantum computing qubit processor.

Here are the worst performing ASX small cap stocks at 12pm Monday August 10:

Swipe or scroll to reveal the full table. Click headings to sort.

Farm Pride Foods (ASX:FRM) fell after confirming that the Lethbridge facility in Victoria has tested positive for H7N7 avian influenza virus.

The approximate number of hens lost represents about 30 per cent of the companys productive hen flock, it says.

The full financial impact of this event is still being determined but is considered material.

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ASX Small Cap Lunch Wrap: Who's beating expectations today? - Stockhead

Quantum Computing Market 2020: Comprehensive Insights

The GlobalQuantum Computing Marketreport is one of the most comprehensive and important additions to MarketResearch.Bizs market research archive. It offers detailed research and analysis of key aspects of the global Quantum Computing market. The market analysts who produced this report provided in-depth information on the leading growth drivers, constraints, challenges, trends, and opportunities to provide a comprehensive analysis of the global Quantum Computing market. Market participants can use market dynamic analysis to plan effective growth strategies and prepare for future challenges in advance. Each trend in the global Quantum Computing market is carefully analyzed and investigated by market analysts.

For Better Understanding, Download Free Sample PDFof Quantum Computing Market Research Report @https://marketresearch.biz/report/quantum-computing-market/request-sample

List of Key Players of Global Quantum Computing Market growth report (2020-2029):

International Business Machines (IBM) Corporation, Google Inc, Microsoft Corporation, Qxbranch LLC, Cambridge Quantum Computing Ltd, 1QB Information Technologies Inc, QC Ware Corp., Magiq Technologies Inc, D-Wave Systems Inc, Rigetti Computing

Production, consumption, revenue, market share, and growth rate are the key targets for Quantum Computing Market forecast from 2013 to 2029 (forecast) in these regions:

North America (U.S., Canada, Mexico).

Europe (UK, Germany, France, Russia, Rest of Europe, Italy).

Asia-Pacific (China, Japan, South Korea, India, Southeast Asia, Rest of Asia-Pacific).

South America (Argentina, Brazil, Columbia, Rest of South America).

The Middle East & Africa (Saudi Arabia, UAE, Egypt, Nigeria, South Africa, Rest of MEA).

Inquire/Speak To Expert for Further Detailed Information About Quantum Computing Report:https://marketresearch.biz/report/quantum-computing-market/#inquiry

Key takeaways of the Quantum Computing market report are listed below:

1) Global Quantum Computing Market trend, Market Size Estimates, Industry Scope, and Division.

2) Competitive analysis is specified for prominent Quantum Computing players, price structures, and value of production.

3) Focuses on the top Quantum Computing manufacturers, to study the capacity, production, value, market share, and development plans in the future.

4) Global Quantum Computing Market Drivers, Opportunities, Emerging Sectors, and Recent Plans and Policies are shown.

5) The current status of the global Quantum Computing Market, current market & the two regional and region levels.

6) Analyze market opportunities for stakeholders by identifying high-growth segments.

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Key questions answered in the report:

What will the market growth rate of Quantum Computing market?

What are the key factors driving the global Quantum Computing market size?

Who are the key manufacturers in Quantum Computing market space?

What are the market opportunities, market risk and market overview of the Quantum Computing market?

What are sales, revenue, and price analysis of top manufacturers of Quantum Computing market?

Who are the distributors, traders, and dealers of Quantum Computing market?

What are the Quantum Computing market opportunities and threats faced by the vendors in the global Quantum Computing industries?

What are sales, revenue, and price analysis by types and applications of Quantum Computing market?

What are sales, revenue, and price analysis by regions of Quantum Computing industries?

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Quantum Computing Market Newest Research Report In PDF by Future Trend, Growth Rate, Opportunity, Industry Experts Analysis - eRealty Express

The presenters planto review a recent study highlighting how Mukais performance compares to other solvers in terms of time-to-solution and diversity of solutions running quantum computing software tools

Quantum Computing Inc () is launching a series of free webinars featuring its Mukai quantum computing software execution platform designed to show how it can solve real-world optimization problems at breakthrough speed.

The programs will be hosted by Steve Reinhardt, the companys VP of business development and an expert in quantum software. He has built software and hardware that has delivered new levels of speed and performance, the company said, including Research T3E distributed-memory systems, Star-P parallel-MATLAB software, YarcData/Cray Urika graph-analytic systems and others.

The first session, titled, The Value of QuOIR Running on the Mukai Platform; Use Cases and Examples will be held at noon ET on July 14. It will focus on the ways Mukai can solve complex, real-world optimization problems faced by major companies and government agencies worldwide, such as logistics routing, drug design and manufacturing scheduling.

The presenters planto review a recent study highlighting how Mukais performance compares to other solvers in terms of time-to-solution and diversity of solutions running quantum computing software tools on classical computers.

Participants will learn about how the QuOIR constrained-optimization layer of the Mukai platform makes it easier to achieve superior performance by automatically creating a machine learning pattern-matching technique called QUBO, the company said.

Registration for the first session can be done here.

The second session, titled, The Mukai How To Webinar, is scheduled for noon ET on July 21. This program will explore the functions of the Mukai quantum computing software execution platform with a focus on how developers and organizations can migrate existing applications to quantum-ready solutions, even on classical computers.

Participants will learn how they can start a free trial of Mukai, which the company launched last week. The webinar will teach how to use the Mukai API for calling a set of quantum-ready solvers that can execute on a cloud-based classical computer infrastructure and deliver differentiated performance for quantum-ready algorithms.

Registration for the second session can be done here.

Contact Andrew Kessel at [emailprotected]

Follow him on Twitter @andrew_kessel

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Quantum Computing to host two webinars showing users the ropes on its Mukai quantum software - Proactive Investors USA & Canada

PQShield, a London-based cybersecurity startup that specialises in post-quantum cryptography, has come out of stealth mode with a 5.5 million seed investment from Kindred Capital, Crane Venture Partners, Oxford Sciences Innovation and angel investors including Andre Crawford-Brunt, Deutsche Banks former global head of equities.

According to the startup, quantum computers promise an unprecedented problem for security, since they will be able to smash through traditional public-key encryption and threaten the security of all sensitive information, past and present. For that reason, the company is developing quantum-secure cryptography, advanced solutions for hardware, software and communications that resist quantum threat yet still work with todays technology.

Whether cars, planes or other connected devices, many of the products designed and sold today are going to be used for decades. Their hardware may be built to last, but right now, their security certainly isnt. Future-proofing is an imperative, just as it is for the banks and agencies that hold so much of our sensitive data, explains founder and CEO Dr. El Kaafarani,

The team, a spin out from Oxford University, is already working on commercialisation and roll-out as well. Its System on Chip (SoC) solution, built fully in-house, will be licensed to hardware manufacturers, while a software development kit will enable the creation of secure messaging apps protected by post-quantum algorithms. Bosch is already a customer.

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London's PQShield raises 5.5 million seed to develop security solutions that match the power of quantum computing - Tech.eu

CHICAGO, July 8, 2020 The Chicago Quantum Exchange, a growing intellectual hub for the research and development of quantum technology, has added to its community seven new corporate partners in computing, technology and finance that are working to bring about and primed to take advantage of the coming quantum revolution.

These new industry partners are Intel, JPMorgan Chase, Microsoft, Quantum Design, Qubitekk, Rigetti Computing, and Zurich Instruments.

Based at the University of Chicagos Pritzker School of Molecular Engineering, the Chicago Quantum Exchange and its corporate partners advance the science and engineering necessary to build and scale quantum technologies and develop practical applications. The results of their workprecision data from quantum sensors, advanced quantum computers and their algorithms, and securely transmitted informationwill transform todays leading industries. The addition of these partners brings a total of 13 companies in the Chicago Quantum Exchange to work with scientists and engineers at universities and the national laboratories in the region.

These new corporate partners join a robust collaboration of private and public universities, national laboratories, companies, and non-profit organizations. Together, their efforts with federal and state support will enhance the nations leading center for quantum information and engineering here in Chicago, said University of Chicago Provost Ka Yee C. Lee.

The Chicago Quantum Exchange is anchored by the University of Chicago, the U.S. Department of EnergysArgonne National LaboratoryandFermi National Accelerator Laboratory(both operated for DOE by UChicago), and theUniversity of Illinois at Urbana-Champaign, and includes theUniversity of Wisconsin-MadisonandNorthwestern University.

Developing a new technology at natures smallest scales requires strong partnerships with complementary expertise and significant resources. The Chicago Quantum Exchange enables us to engage leading experts, facilities and industries from around the world to advance quantum science and engineering, said David Awschalom, the Liew Family Professor in Molecular Engineering at the University of Chicago, senior scientist at Argonne, and director of the Chicago Quantum Exchange. Our collaborations with these companies will be crucial to speed discovery, develop quantum applications and prepare a skilled quantum workforce.

Many of the new industry partners already have ongoing or recent engagements with CQE and its member institutions. In recent collaborative research, spectrally entangled photons from a Qubitekk entangled photon source were transported andsuccessfully detectedafter traveling through one section of theArgonne quantum loop.

On another project, UChicago computer scientist Fred Chong and his students worked with both Intel and Rigetti Computing on software and hardware solutions. With Intels support, Chongs team invented a range of software techniques to more efficiently execute quantum programs on a coming crop of quantum hardware. For example, they developed methods that take advantage of the hierarchical structure of important quantum circuits that are critical to the future of reliable quantum computation.

Chicago Quantum Exchange member institutions engage with corporate partners in a variety of collaborative research efforts, joint workshops to develop new research directions, and opportunities to train future quantum engineers. The CQE has existing partnerships with Boeing; IBM; Applied Materials, Inc.; Cold Quanta; HRL Laboratories, LLC; and Quantum Opus, LLC.

The CQEs newest corporate partnerships will help further research possibilities in areas from quantum communication hardware, to quantum computing systems and controls, to finance and cryptography applications.

Jim Clarke, director of quantum hardware at Intel, looks forward to further collaborations with Chicago Quantum Exchange members.

Intel remains committed to solving intractable challenges that lie on the path of achieving quantum practicality, said Clarke. Were focusing our research on new qubit technologies and addressing key bottlenecks in their control and connectivity as quantum systems get larger. Our collaborations with members of the Chicago Quantum Exchange will help us harness our collective areas of expertise to contribute to meaningful advances in these areas.

The Chicago Quantum Exchanges partnership with JPMorgan Chase will enable the use of quantum computing algorithms and software for secure transactions and high-speed trading.

We are excited about the transformative impact that quantum computing can have on our industry, said Marco Pistoia, managing director, head of applied research and engineering at JPMorgan Chase. Collaborating with the Chicago Quantum Exchange will help us to be among the first to develop cutting-edge quantum algorithms for financial use cases, and experiment with the power of quantum computers on relevant problems, such as portfolio optimization and option pricing.

Applying quantum science and technology discoveries to areas such as finance, computing and healthcare requires a robust workforce of scientists and engineers. The Chicago Quantum Exchange integrates universities, national laboratories and leading companies to train the next generation of scientists and engineers and to equip those already in the workforce to transition to quantum careers.

Microsoft is excited to partner with the Chicago Quantum Exchange to accelerate the advancement of quantum computing, said Chetan Nayak, general manager of Microsoft Quantum Hardware. It is through these academic and industry partnerships that well be able to scale innovation and develop a workforce ready to harness the incredible impact of this technology.

Source: Chicago Quantum Exchange

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Chicago Quantum Exchange Welcomes Seven New Partners in Tech, Computing and Finance - HPCwire

On sci-fi thriller Devs, VFX supervisor Andrew Whitehurst reteamed with director Alex Garland for an exploration of the multiverse, digging into scientific literature to depict a world of the near future, and the technology that accompanied it.

Starring Sonoya Mizuno, the series centers on Lily, a software engineer for a quantum computing company in the Bay Area, who investigates a secretive development division within her company, following the mysterious disappearance of her boyfriend.

An Oscar winner known for films including Ex Machina and Annihilation, Whitehurst began conversations on Devs while the latter film was being finished. [Alex and I] were talking a lot during the period of him writing it, because we both have a shared interest in quantum physics, and the idea of multiverses. I was being sent episodes as they were being written, and discussing what he was about to go and write before he was writing it, Whitehurst says. So, it was probably the most involved Ive ever been in that part of a production, which is lovely.

In early conversations with Garland, Whitehurst understood that visual effects would play out in two branches throughout the show. What art departments cant build, we would have to augment or extend, or in some cases, replace. So, theres that sort of invisible worldbuilding aspect to it, which we knew we were going to have to do, because the scope of the vision was so big, he explains. We knew our art department would do something amazing, but we were going to be in the business of making the world complete.

From Whitehursts perspective, the other of the two aforementioned branches was much more creatively driven, representing a singular kind of challenge. Essentially, in his work on Devs, Whitehurst would have to visualize life inside a multiverse. Secondly, he would have to craft outputs, or visualizations, emerging from a quantum computer at Devsthe development division that gives the series its name. Created by obsessive scientists Forest (Nick Offerman) and Katie (Alison Pill), this machine has the ability to predict the future, and visually project into the past, presenting grainy depictions of such figures as Jesus Christ and Joan of Arc.

Prior to production, Whitehurst turned to the writing of physicist David Deutschas he often has throughout his careerfor insights that might inform the visual effects at hand. He wrote an amazing book more than 20 years ago called The Fabric of Reality, which is something that I reread semi-regularly, he says. His notion of trying to come up with this theory of everything that can describe, using scientific ideas, this whole universe, was something that was very appealing, as a philosophical basis to build off.

On a practical level, the VFX supervisor experimented early on with the way he would manifest a multiverse, and the quantum computers visualizations, recognizing that the choices he made would have a direct impact on the way the show was shot. For the multiverse stuff, we needed to know what we were aiming for the finished effect to look like, so we knew what to shoot on set to be able to do that. Then, with the visualizations that you see on the screens inside the [Devs] cube, we were hoping to be able to, and ultimately were able to, project most of that footage live on set, when you were actually shooting those scenes, so that it could act as a light source, Whitehurst explains. It gave the actors something to react to; it gave [DP] Rob [Hardy] something to frame up on.

When it came to multiverse footagewhich featured multiple versions of an actor on screenWhitehurst engaged in a series of tests, shooting various versions of people doing very similar actions, before blurring them, and layering them together. That had this very Francis Bacon look to it, which was kind of cool. But it didnt describe the idea of many different worlds clearly enough. So, that was an iterative process, the artist reflects. We ended up going, Look. The way that we should do this, that we should represent the many worlds, is by being able to see each distinct person in their own world of the multiverse. And were just going to layer that together.

In the design process for the visualizations, Whitehurst asked himself, how would the quantum computer visually generate a world for people to look at? Again, we went through a lot of different ideas of building it up in blocks, or building it up as clouds. And ultimately, the way that modern computer renderers work, which is the piece of software that generates our CG pictures, is that it works by doing continually refining passes, he explains. So, when you say, Render me this scene, the first thing youre presented with is this very sandy, rough version of the image, and then it gets slightly less rough, and slightly less rough, and the sandiness goes away, and it becomes clearer, and clearer, and clearer.

For Garland and his VFX supervisor, this understanding of real-world rendering lent itself to an interesting visual ideaand so over the course of Devs, we see that the computer is getting better at creating its images over time. We took that idea, and we actually ended up coming up with this sort of 3D volume of these points drifting around, as if they were little motes of dust suspended in water. The computer is generally coaxing these points to be specific objects in a certain space, and as they get better and better at it, the points become denser, and the object becomes clearer and clearer, Whitehurst says. That ended up being a narratively satisfying approach to designing that visual effect, but also it had a real aesthetic quality to it, as well. So, that was kind of a double win for us, really.

The visuals that appear on the massive Devs screen were all first photographed as plates, which would serve as a base for Whitehursts creations. We had a performer to be Joan of Arc, and we had a series of actors to be Lincoln, and the other people at the Gettysburg Address. Those were filmed in a car park at Pinewood [Studios], and then we would track those, and isolate them, so that we could put them into three-dimensional space, the VFX supervisor says. Then, we would create digital matte painting environments, and we were able to build up this scene, which had depth, which we could then, using the simulation software that wed developed, push these points around, so that they could attempt to try and stick themselves to the forms of these people. And the amount that they stuck to that form determined how clear they were.

In terms of the invisible worldbuilding Whitehurst tackled for the series, one of the biggest challenges, and most distinct examples, was the Devs cubethe beautifully futuristic center of the development divisions operations. Encased in reflective golden walls, the cube was an office, which workers entered into, by way of a floating capsule on a horizontal path.

Art departments were constrained by the size of the biggest soundstage that we could find, which happened to be in Manchester. What they were able to build was the office level of the floating cube, the gold walls that surround it, the gap in between, and a glass capsule, which was mounted on a massive steel trolley that could be pushed backwards and forwards by grips, Whitehurst shares. But everything thats above and below that had to be a visual effect. Then, any angles where you were particularly low, looking up, or particularly high, looking down, also had to be full visual effect shots, because you couldnt get the camera that high or that low, because of the constraints of the space.

Most dialogue scenes within the Devs cube were realized in-camera, given that the camera department was following people on the office floor, with a level lens. But basically, anything thats above or below the office floor in that environment is digital, the VFX supervisor notes. And obviously, you had to paint out the trolley that the capsule was on, and replace that section of the environment with a digital version.

Another impressive example of the series VFX worldbuilding was the massive statue of Amaya, which towered over the redwood trees on the Devs campus. Present very little on screen, this little girl is more of a specteran absence that permeates and haunts the world of Devs. That [statue] was fully CG, Whitehurst says. The location that its sat in is the amphitheater at the University of California, Santa Cruz. So, they had a stage area, and its like, Well, the statue will be standing on that.

Taking into consideration the environment in which the statue would stand, Whitehurst then had to consider in depth how it would look. We did a photogrammetry session, which is where you are able to take multiple photographs instantaneously of a subjectin this case, the little girl. From that, you can build a 3D model. So, its a sort of snapshot in time that you can then create into something 3D, the VFX supervisor says. We used that as the basis of our digital sculpt then to make the statue, and then we went through a long process of, Well, should this be a piece of pop art? Should it have a sort of Jeff Koons quality to it? Or should we go for something that feels like its made out of concrete?

We tried a whole bunch of different surfacing approaches, and how would it catch the light if it was made of concrete, or if it was enamel paint, and eventually, the pop art approach felt narratively the most appropriate, he adds. So, thats what we ended up going with.

For Whitehurst, there were a great number of creative challenges in designing visual effects for Devs. Certainly, I think the complexity of some of the environmentsso, the cube with the permanently shifting lighting on it, where were having to match all of those lighting changeswas very tricky. Getting this sort of aesthetic balance in things like the visualizations, making it feel something that felt scientifically plausible, but also had a sense of beauty. And how much should we allow the audience to see, and how mysterious should it be? he says. That sort of thing was complex.

The series was also notable for Whitehurst, given that it was the first he had ever taken on. Most of us working on the series come from a film background. But I think the key thing that is most exciting about it, and particularly for someone like Alex, who is so big-ideas-driven, and writes characters so well, is having something where you get to spend more time with those characters, he says. You really get to flesh out and develop those big ideas, which is something that all of the rest of us working on it can help with.

The other highlight is, I got to work with some of my favorite people, again, for the third time, Whitehurst adds. So, it was an exciting mixture of very familiar, in terms of most of the people I was working with, and something excitingly new at the same time.

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VFX Supervisor Andrew Whitehurst Grapples With The Intricacies Of Quantum Physics On Sci-Fi Thriller Devs - Deadline