Defense Advanced Research Projects Agency (DARPA)’s Post

Quantum computing is one of the most potentially disruptive technologies out there with the promise of vastly outperforming traditional computing across a number of key tasks and benchmarks. It's also one of the more difficult technologies to get ones head around if your background isn't in quantum mechanics or a similar field. The concepts are straightforward but also counterintuitive. I'm glad to see DARPA focusing a lot of attention on quantum computing because when it comes to cyber security and other tasks that are critical to ensuring our national security, it certainly could be a highly disruptive game changer. We've been involved in staffing a couple quantum computing projects and it's certainly interesting to watch the incremental progress in the field.

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Since the 16th and 17th centuries, scientific discovery has followed the iterative process of the scientific method: observation, hypothesis development, and testing with physical experiments. This process remained largely unchanged until the mid-20th century when digital computers revolutionized scientific research by enabling detailed simulations of physical phenomena. Over the last century, computational tools have transformed scientific discovery, allowing for rapid and cost-effective hypothesis testing before physical experiments. However, fields involving quantum mechanical effects have not seen the same benefits from computational advances. Simulating quantum physics requires exponentially increasing classical computing resources with each additional quantum particle, limiting the scope of quantum systems that can be studied. Despite successes in specific cases, the lack of scalable and accurate quantum simulation tools has hindered understanding in areas like superconductivity, chemistry, and magnetism. This challenge inspired Feynman’s proposal for a quantum computer in the 1980s. Recently, the first generation of these devices, known as Noisy Intermediate Scale Quantum (NISQ) computers, has emerged, though they face challenges with noise and scalability. The next generation of quantum computers is expected to leverage error correction for fault-tolerant quantum computation. This technological progress hints at the potential for quantum mechanical systems to undergo a computer-accelerated scientific discovery, similar to what classical physics has experienced. More 👇 #quantuminformationscience

Exciting advancements in quantum computing offer a glimpse into a future where animal experiments could be reduced and cures for diseases like cancer may be within reach. A Swiss start-up, focusing on artificial lungs, aims to leverage quantum algorithms to enhance efficiency and contribute to medical breakthroughs, potentially eliminating the need for animal testing. Private investment is propelling Swiss start-ups towards commercial use of quantum computers, although the technology's full capabilities are still being explored. This development coincides with a competitive landscape among tech giants like Google and IBM striving to push the boundaries of quantum computing. Join the conversation on the potential and pitfalls of this cutting-edge technology. #QuantumComputing #MedicalBreakthroughs #Innovation #TechAdvancements

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Quantum computing may sound like a far-fetched idea, but its development is well underway at IBM Research. We invited Fast Company Company to visit Thomas J. Watson Research Center so they can meet the minds behind the new IBM System Two, our largest and most powerful quantum computer to date. Head to the full article to learn about the challenges of developing #quantum systems and what’s next for the technology. https://bit.ly/48EYKJT

How will Dirac-3 improve the quantum computing industry?  Discrete optimization problems require the identification of the best solution from a distinct set of possibilities. Problems that require solving are applicable to a wide range of fields, including scheduling, logistics, network design, data analysis and even drug discovery.  Dirac-3 can effectively solve optimization problems in quantum computing. It is built on a cost function that is different from the Ising Hamiltonian that typically has quadratic interaction terms over qubits. Dirac-3 supports higher interactions among high dimensional quantum states (qudits).  ✔ Dirac-3 naturally represents non-binary discrete optimization problems   ✔ It involves k-body interaction terms instead of being limited to the first and second order terms   Dirac-3 eliminates additional complex encoding steps and the incorporation of auxiliary parts that usually add to the complexity of the problem which an Ising solver is familiar with. #dirac3 #quantumcomputing #changingquantum #dirac3computing #complezproblems #encoding #optimizationproblems #hardproblems #problemsolving #computer #discretesolving #qudits #qubits #photonics #QCi  

Quantum computing is no longer a futuristic concept; it is transforming industries today. This The Wall Street Journal article highlights some of the practical applications and immense potential of this technology. My 5 Key Takeaways 1. Real-World Impact: As we see in the article, quantum computing is optimizing complex tasks like delivery scheduling and airport operations. ✅ QuantumBasel already is in touch with European airports; looking forward to share results. 2. Technological Progress: Significant advancements in processing power are enabling quantum computers to solve previously intractable problems. ✅ QuantumBasel has a variety of partnerships ensuring always to be ahead of the curve. 3. Broad Adoption: Various sectors, including finance and healthcare, are adopting quantum solutions to enhance efficiency and address complex challenges. ✅ We already are discussing the impact to the financial services sectors; results to be published this year already. 4. Scientific Milestones: Achievements in computational supremacy underscore quantum computing’s superior performance over traditional supercomputers for specific tasks. ✅ Our quantum scientists are active in publishing papers and interacting with multiple universities. 5. Global Potential: Quantum technology, as discussed in the article, is poised to tackle major global challenges such as climate change and food security. ✅ QuantumBasel is actively seeking sustainability challenges to support with our technology and applications. At QuantumBasel, we are excited about our collaboration with international airports, financial service institutions, logistic companies and many more. Looking forward to sharing the results of our work. 👉🏻 Connect with us to discover tailored quantum solutions that meet YOUR business needs. #quantumcomputing #thoughtlesdership uptownBasel Dr. Frederik Flöther Sonja Andrist Robby Toole Matteo Krummenacher Jan Mikolon Sophie Peggs Julien Baglio, Ph.D. Rajiv Krishnakumar Nadine Kugler Hans-Jörg Fankhauser Baschi Dürr Claudia Fricker Janine Goldiger https://lnkd.in/esKJiCQe

#UofTArtSci alum Nathan Killoran wants to make sure no one is left behind when quantum computers transform life as we know it. Quantum computers are revolutionizing drug discovery to enhance financial modelling and our understanding of world economies. This technology is advancing rapidly by leveraging quantum mechanics to solve complex problems that today’s computers can’t handle and may soon be at the forefront of commercial use. Read the full A&S story: https://bit.ly/49fIjnV