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TOKYO, May 17, 2023 /PRNewswire/ -- QunaSys, a quantum computing software company, is excited to invite students, researchers, and anyone learning and researchingquantum computation and quantum chemistry worldwide to participate in the Quantum Algorithm Grand Challenge (QAGC).

The challenge began on May 3, 2023, and the final submission deadline is July 31, 2023. The top four individuals or teams will have the opportunity to present their algorithms at the workshop hosted by QunaSys during IEEE Quantum Week 2023, taking placein Seattle, USA from September 17 to 22, 2023.Additionally, the top three individuals or teams will receive cash prizes: USD 10,000 for the first place, USD 5,000 for the second place, and USD 3,000 for the third place.

Contest-based research has successfully driven industrialization in fields like machine learning and robotics. It involves benchmarking real problems and competing for improvements. QAGC provides a quantum algorithm platform that evaluates proposed algorithms based on the same criteria, inspiring researchers worldwide to enhance their algorithms through competition. The ultimate goal is to expedite the industrial implementation of quantum computing.

The challenge problem for QAGC is to calculate the ground energy of the modified Fermi-Hubbard model, which closely resembles molecular problems but with a known exact solution. Using this model enables benchmark beyond classically simulatable size. The evaluation will be based on accuracy, measured by the absolute difference between proposed results and the exact solution. The evaluation system will consist of 8 qubits, and the estimated running time should not exceed 1000 seconds.

QAGC presents a perfect opportunity for quantum computing enthusiasts to showcase their skills and creativity. By participating, you will have the chance to push the boundaries of NISQ algorithms and contribute to the advancement of quantum computing technology. Additionally, you will gain valuable insights from other researchers and developers worldwide while becoming part of the thriving quantum computing community.

Join the race today to take NISQ algorithms to the next level! Register for the Quantum Algorithm Grand Challenge now. To learn more about the challenge and how to participate, visit https://www.qagc.org/for further information.

ContactQAGC secretariat: [emailprotected]

SOURCE QunaSys Inc.

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QunaSys Launches "Quantum Algorithm Grand Challenge": Join the ... - PR Newswire

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by Ingrid Fadelli , Phys.org

Over the past decades, researchers and companies worldwide have been trying to develop increasingly advanced quantum computers. The key objective of their efforts is to create systems that will outperform classical computers on specific tasks, which is also known as realizing "quantum advantage."

A research team at D-Wave Inc., a quantum computing company, recently created a new quantum computing system that outperforms classical computing systems on optimization problems. This system, introduced in a paper in Nature, is based on a programmable spin glass with 5,000 qubits (the quantum equivalents of bits in classical computing).

"This work validates the original hypothesis behind quantum annealing, coming full circle from some seminal experiments conducted in the 1990s," Andrew D. King, one of the researchers who carried out the study, told Phys.org.

"These original experiments took chunks of spin-glass alloy and subjected them to varying magnetic fields, and the observations suggested that if we made a programmable quantum spin glass, it could drive down to low-energy states of optimization problems faster than analogous classical algorithms. A Science paper published in 2014 tried to verify this on a D-Wave Two processor, but no speedup was found."

In their recent work, King and his colleagues realized quantum acceleration by boosting the connectivity and coherence of the D-Wave Advantage processor, a quantum computing system recently developed at D-Wave. They ultimately pushed this processor into a coherent annealing regime with no thermal effects, which was not achieved in previous works.

To attain this, the researchers programmed a 5,000-qubit spin glass system that they could then control. They then used this system to tackle different optimization problems. Artist's interpretation of a 3D optimization problem solved with a D-Wave Advantage processor. Credit: D-Wave.

"This is a 'full circle' moment, in the sense that we have verified and extended the hypothesis of the UChicago and NEC researchers; quantum annealing shows a scaling advantage over simulated thermal annealing," King said. "Ours is the largest programmable quantum simulation ever performed; reproducing it classically is way beyond the reach of known methods."

To realize coherent annealing rigorously and reliably, the team first developed a 2,000-qubit system and applied it to a simple 1D problem that can be precisely solved with classical computing methods. In their new study, on the other hand, they developed a system with over double the number of qubits and applied it to a problem that cannot be simulated using classical computing tools.

"For several reasons, D-Wave annealing-based quantum computers are the only quantum platform that can solve this kind of optimization problem," King said. "The first is size: we looked at scaling behavior from very small spin glasses (250 qubits) to very large (5,000+ qubits); 250 is pretty much the upper limit for other platforms. The second reason is programmability: we programmed qubit networks in a three-dimensional geometry, tuning each individual qubit-qubit interaction individually."

The researchers performed their experiments on an online production system, which means that they could run alongside their cloud customer activities. In this online platform and with their 5,000-qubit spin glass system, they finally demonstrated scaling advantage on optimization problems.

"We have a clear view of quantum effects and very clear evidence, both theoretical and experimental, that the quantum effects are conferring a computational scaling advantage over classical methods," King said. "We want to highlight the difference between this original definition of quantum advantage and the fact that it is sometimes used as a stand-in term for quantum supremacy, which we have not demonstrated. Gate-model quantum computers have not shown any capabilities approaching this for optimization, and I personally don't believe they ever will."

In light of their recent work, King and his colleagues believe that quantum annealing will always perform better than gate-model on optimization problems. This is why D-Wave is currently focusing on the development of both these platforms.

"For a long time, it was subject for debate whether or not coherent quantum dynamics were playing any role at all in quantum annealing," King said. "While this controversy has been rebuked by previous works, this new research is the clearest demonstration yet, by far."

The work by this team of researchers and the 5,000-qubit system they realized is a significant contribution to the field of quantum computing, which specifically highlights the potential of tackling optimization problems using quantum computing systems. Their recent paper focused on attaining quantum advantage over classical systems on optimization problems by precisely controlling the quantum dynamics of a large system. In their future works, however, King and his colleagues would also like to quantify how limited classical methods are and show that the capabilities of their system can reach beyond those of supercomputers.

"We can also see the effects of coherence in our processors very clearly," King added. "The Advantage2 processor, currently in development, promises significant improvements in that area, so we're really excited to see what we can do, not only in terms of improved optimization for customer applications, but also with more exotic experiments in coherent annealing."

More information: Andrew D. King et al, Quantum critical dynamics in a 5,000-qubit programmable spin glass, Nature (2023). DOI: 10.1038/s41586-023-05867-2

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Team demonstrates quantum advantage on optimization problems with a 5,000-qubit programmable spin glass - Phys.org

DUBLIN, May 17, 2023 /PRNewswire/ -- The "Growth Opportunities in Wearables, Artificial Intelligence, Quantum Computing and 5G Communication" report has been added to ResearchAndMarkets.com's offering.

The Microelectronics Technology Opportunity Engine focuses on innovations related to hardware modules for space shuttles, flexible batteries for wearables, chiplet interconnects, stroke detection wearables, wearable rings for glucose monitoring, energy-efficient ICs, a processor for quantum computing, efficient FPGAs and DRAM, quantum computing hardware, power supply architecture for ICs, AI processors, GaN HEMT, and RF for 5G communication.

The Microelectronics Technology Opportunity Engine captures global electronics-related innovations and developments on a weekly basis. Developments are centered on electronics attributed by low power and cost, smaller size, better viewing, display and interface facilities, wireless connectivity, higher memory capacity, flexibility and wearables.

Research focus themes include small footprint lightweight devices (CNTs, graphene), smart monitoring and control (touch and haptics), energy efficiency (LEDs, OLEDs, power and thermal management, energy harvesting), and high speed and improved conductivity devices (SiC, GaN, GaAs).

Key Topics Covered:

1. Innovations in Microelectronics

2. Appendix

A selection of companies mentioned in this report includes

For more information about this report visit https://www.researchandmarkets.com/r/4wrffg

About ResearchAndMarkets.comResearchAndMarkets.com is the world's leading source for international market research reports and market data. We provide you with the latest data on international and regional markets, key industries, the top companies, new products and the latest trends.

Contact:

Research and MarketsLaura Wood, Senior Manager[emailprotected]For E.S.T Office Hours Call +1-917-300-0470For U.S./CAN Toll Free Call +1-800-526-8630For GMT Office Hours Call +353-1-416-8900U.S. Fax: 646-607-1907Fax (outside U.S.): +353-1-481-1716

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One of the challenges in quantum computing is overcoming 3D spin-glass optimization limitations, which can slow down quantum simulation meant to solve real-world optimization problems. An experimental solution is D-Waves Advantage quantum computer, running spin-glass dynamics (essentially a sequence of magnets) on 5,000 qubits.

According to a study by scientists from D-Wave and Boston University, published in the journal Nature, the team has validated that quantum annealing a mathematical process used to find low-energy states by using quantum fluctuations can improve solution quality faster than classical algorithms, at least theoretically. It may be a key step forward in showing the ways in which a quantum processor can compute coherent quantum dynamics in large-scale optimization problems.

D-Wave customers who subscribe to the Leap quantum cloud service can access the new commercial-grade, annealing-based quantum computer as of April 19.

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The main takeaway for enterprises is that spin-glass computing on a quantum annealing device may eventually be able to efficiently solve optimization problems, achieving a goal with as little energy as possible. For example, it could be a relatively efficient way to answer questions such as Should I ship this package on this truck or the next one? or the traveling salesman problem (What is the most efficient route a traveling salesperson should take to visit different cities?), as D-Wave wrote.

D-Wave is one of the only companies that offers enterprise quantum computing space with both gate and annealing programs, which now includes its 5,000 qubit, commercial-grade Advantage quantum computer. There is still some question as to how practical this technology is, but the new paper is proof that further commercial quantum computing optimization can be performed on D-Waves hardware.

SEE: Should IT teams factor quantum computing into their decisions?

Getting deeper into the physics, spin glasses are often used as test beds for paradigmatic computing, the researchers said, but using this approach in a programmable system and therefore one that can be used to do practical calculations still leads to potential problems. D-Wave has solved this on its hardware by using quantum-critical spin-glass dynamics on thousands of qubits with a superconducting quantum annealer.

The same hardware that has already provided useful experimental proving ground for quantum critical dynamics can be also employed to seek low-energy states that assist in finding solutions to optimization problems, said Wojciech Zurek, theoretical physicist at Los Alamos National Laboratory and leading authority on quantum theory, in D-Waves press release.

Applications that solve optimization problems like the packaging shipping question above require a minimum energy state from the quantum annealing processors they run on. Other calculations that could be used for decision-making, such as probabilistic sampling problems, need good low-energy samples in order to run.

D-Wave says spin glasses can be brought into low-energy states faster by annealing quantum fluctuations than by conventional thermal annealing.

This paper gives evidence that the quantum dynamics of a dedicated hardware platform are faster than for known classical algorithms to find the preferred, lowest energy state of a spin glass, and so promises to continue to fuel the further development of quantum annealers for dealing with practical problems, said Gabriel Aeppli, professor of physics at ETH Zrich and EPF Lausanne, and head of the Photon Science Division of the Paul Scherrer Institut.

Another problem researchers in the quantum computing world are trying to solve is qubit coherence. In a simplified sense, coherence means that a quantum state maintains certain physical qualities while in use. Research shows that coherent quantum annealing can improve solution quality faster than classical algorithms.

Hand-in-hand development of the gate and annealing programs will bring us to longer coherence times and better qubit parameters, allowing our advantage over classical optimization to grow, Andrew King, director of performance research for D-Wave, wrote in a blog post.

Quantum annealing can be used for a wide range of practical optimization applications, Murray Thom, vice president of quantum business innovation at D-Wave, told TechRepublic. For example, it is already being used today to optimize supply chains, employee scheduling, e-commerce delivery, missile defense, protein folding, fraud detection, and industrial manufacturing, just to name a few.

While the newly published research was conducted on the currently commercially available Advantage quantum computer, D-Wave is also working on its next iteration. The Advantage2 system is in the experimental prototype stage and will be D-Waves sixth-generation quantum computing hardware. D-Wave anticipates the full Advantage2 system will launch with 7,000 qubits and does not have a projected release date for the alpha version.

Moving forward, we expect to see annealing quantum computers increase their business impact as technological enhancements in qubit coherence yield higher quality solutions and enable higher connectivity architectures, Thom said.

He expects over the next five years to see more development of gate model systems, an alternative to quantum annealing which has seen some interest from the pharmaceutical industry.

Scalable, error-corrected gate-model machines will begin to emerge and begin to show early business value, he said.

D-Wave competes with other quantum computing systems and software providers such as Rigetti Computing, Google, IBM, Honeywell, and IonQ.

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Quantum computing gets hardware boost with D-Waves spin glass breakthrough - TechRepublic

UFC commentator, Joe Roganhas achieved great success as a podcaster. The biggest reason behind the success of The Joe Rogan Experience is how it entertains people of different interests. Even though Rogan has been an MMA analyst for over two decades, he never made his podcast all about MMA. The 55-year-old invites guests from all walks of life to his show, and that can vary from comedians to scientists. Other than MMA, Rogan has always shown a keen interest in science and technology. He loves to dig deeper into the unknown secrets of the world. Moreover, he is fascinated by the growth of technology over time.

In JRE, the former Fear Factor host has often expressed his concern over the uncontrollable growth of technology. Rogan fears a world where science and technology overpower human efficiency. In a recent episode of JRE, the UFC commentator talked to Dr Michio Kaku. Kaku is a professor of theoretical physics. The two discussed a lot about the tremendous growth of technology over the years.

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In the #1980 episode of JRE, Rogan and Dr Michio Kaku connected the realities of the world to the movie The Matrix. Kaku had written a book called Quantum Supremacy: How the Quantum Computer Revolution Will Change Everything.His vast knowledge of quantum computers made the UFC commentator eager to learn more.

During the conversation, Rogan asked, But if we are talking about technology as we currently understand it today, in comparison to technology as they had available to them a thousand years ago. What we do now, thats insane? And you are talking about quantum computing, which is almost available today and you look at thousand years from now. Couldnt you potentially imagine there could be a world where there is technology sufficient to do what we are talking about? To create a version of reality?

Kaku was able to give a clear answer to Rogans query. He said, Well, if you saw the movie we are all in parts and we are all connected to computers, then stimulus, The Matrix. As long as you are stimulating a piece of the matrix, not the whole thing, but as you walk from place to place, the computer reassembles and replicates that place. That may be possible, but not the whole earth.

Rogans questions to Kaku proved the amount of interest he has in science and technology.

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In the very same episode of JRE, Rogan asked Kaku about the quantum computers that have the ability to break any code. Rogan was concerned about the world without secrets. However, Kaku didnt seem worried like Rogan. The professor told him that the secret codes of some nations had been broken in the past as well.

READ MORE: It Was Like an Assassination: Joe Rogan Recalls Mike Tyson at His Destructive Best in His Most Violent Fight

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He went on to explain about World War II, where the secret codes of the Germans were broken using quantum computers. This helped to know the places where Germany was planning to attack beforehand. Back then, it was technology that helped save millions of lives.

Watch This Story:How Did Joe Rogan Become Famous?

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Joe Rogan and Michio Kaku Compare Reality to The Matrix as the Duo Address the Wonders of Quantum Computing - EssentiallySports