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  1. They report that the quantum computer solved an arithmetic task in 200 seconds... for which a conventional supercomputer would have needed 10,000 years.[1]
  2. It has not yet been proven, for example, that a quantum computer can run stably for hours, days or even years.[1]
  3. Get the entire 31-page report Download the free report to learn about the the quantum computing industry landscape and how close we are to quantum supremacy.[2]
  4. A truly universal quantum computer would likely make use of over 100,000 qubits — some estimates put it at 1M qubits.[2]
  5. The basic idea behind the universal quantum computer is that you could direct the machine at any massively complex computation and get a quick solution.[2]
  6. Researchers have been designing algorithms for years that are only possible on a universal quantum computer.[2]
  7. One of the prime examples is quantum computing, an almost legendary form of computing that promises exceptional speed improvements that will revolutionise many aspects of human life.[3]
  8. Quantum computing is one of those technologies that futurists often joke is always a couple of decades away.[3]
  9. The power of the quantum computer comes from the fact that it’s not limited to binary bits (the ones and zeros of traditional computer processors).[3]
  10. Today’s approaches to quantum computing try to solve optimisation problems that have broad cross-sector applicability, like the fine tuning of supply chains.[3]
  11. Nevertheless, like Schrödinger’s cat, the quantum computer’s final calculation emerges only once the qubits are measured and “collapse” their quantum state to either a 1 or 0.[4]
  12. In addition to enabling the instantaneous and secure transfer of information, superimposed qubits can be entangled in a chain-like fashion to exponentially enhance a quantum computer’s power.[4]
  13. For example, a binary computer with eight bits can represent any number between 0 and 225; a quantum computer with eight qubits can represent every number between 0 and 255 at the same time.[4]
  14. Quantum supremacy refers to the moment when a quantum computer is able to outperform a conventional system or accomplish a task otherwise thought impossible even for a powerful supercomputer.[4]
  15. From a social-historical perspective, quantum computing is a domain where experimentalists find themselves ahead of their fellow theorists.[5]
  16. From a more philosophical perspective, advances in quantum computing may yield foundational benefits.[5]
  17. Consequently, experimentalists around the world are engaged in attempts to tackle the technological difficulties that prevent the realisation of a large scale quantum computer.[5]
  18. Published in 1994, this algorithm marked a ‘phase transition’ in the development of quantum computing and sparked a tremendous interest even outside the physics community.[5]
  19. But eight qubits is enough for a quantum computer to represent every number between 0 and 255 at the same time.[6]
  20. A quantum computer harnesses some of the almost-mystical phenomena of quantum mechanics to deliver huge leaps forward in processing power.[7]
  21. Thanks to this counterintuitive phenomenon, a quantum computer with several qubits in superposition can crunch through a vast number of potential outcomes simultaneously.[7]
  22. Quantum computing is essentially harnessing and exploiting the amazing laws of quantum mechanics to process information.[8]
  23. A quantum computer, on the other hand, uses quantum bits, or qubits.[8]
  24. Thanks to superposition and entanglement, a quantum computer can process a vast number of calculations simultaneously.[8]
  25. Think of it this way: whereas a classical computer works with ones and zeros, a quantum computer will have the advantage of using ones, zeros and “superpositions” of ones and zeros.[8]
  26. In October 2019, researchers at Google announced to great fanfare that their embryonic quantum computer had solved a problem that would overwhelm the best supercomputers.[9]
  27. Some said the milestone, known as quantum supremacy, marked the dawn of the age of quantum computing.[9]
  28. However, Greg Kuperberg, a mathematician at the University of California, Davis, who specializes in quantum computing, wasn’t so impressed.[9]
  29. In contrast, a quantum computer employs quantum bits, or qubits, that can be both 0 and 1 at the same time, the equivalent of you sitting at both ends of your couch at once.[9]
  30. A machine capable of living up to the original promise of quantum computing by, for example, cracking conventional encryption, would require millions of individually controllable qubits.[10]
  31. Laboratories have long competed to build the quantum computer with the most qubits.[10]
  32. In June, technology firm Honeywell in Charlotte, North Carolina, claimed to have made the world’s most powerful quantum computer as measured by ‘quantum volume’.[10]
  33. Another measure of power is a quantum computer’s ability to beat a classical machine on a problem — which Google did last year using a 54-quibit machine.[10]
  34. Quantum computing uses the qubit as the basic unit of information rather than the conventional bit.[11]
  35. Quantum computing does not have its own programming code and requires the development and implementation of very specific algorithms.[11]
  36. Computer security, biomedicine, the development of new materials and the economy, are among the fields that may be revolutionised by advances in quantum computing.[11]
  37. Companies like Airbus use quantum computing to design more efficient aircraft.[11]
  38. Quantum computing is the use of quantum phenomena such as superposition and entanglement to perform computation.[12]
  39. Conversely, any problem that can be solved by a quantum computer can also be solved by a classical computer, at least in principle given enough time.[12]
  40. A choice of gate family that enables this construction is known as a universal gate set, since a computer that can run such circuits is a universal quantum computer.[12]
  41. By comparison, a quantum computer could efficiently solve this problem using Shor's algorithm to find its factors.[12]
  42. One rough way to measure a quantum computer’s capability is its number of “qubits”, the analogue of classical computing’s 1-or-0 bits.[13]
  43. IBM , which has invested heavily in quantum computing, reckons it can build a 1,000-qubit machine by 2023.[13]
  44. Explore the making of a quantum computer at the Institute of Physics at the University of Stuttgart Learn about quantum computers.[14]
  45. However, actually building a useful quantum computer has proved difficult.[14]
  46. This type of quantum computer can be extended by using molecules with more individually addressable nuclei.[14]
  47. In fact, in March 2000 Emanuel Knill, Raymond Laflamme, and Rudy Martinez of Los Alamos and Ching-Hua Tseng of MIT announced that they had created a 7-qubit quantum computer using trans-crotonic acid.[14]
  48. In quantum computing, operations instead use the quantum state of an object to produce what's known as a qubit.[15]
  49. For the time being, classical technology can manage any task thrown at a quantum computer.[15]
  50. Quantum computing swaps the deterministic property of “charge vs. no charge” for a quantum property such as an electron’s spin.[16]
  51. This switcheroo from binary to non-binary dramatically increases a quantum computer’s ability to perform multifaceted calculations.[16]
  52. “We can use the quantum processes happening inside a quantum computer to simulate the quantum processes happening inside our experiment,” Ringer says.[16]
  53. “Potentially, the particle physics community could even have an impact on shaping the evolution of quantum computing by proposing interesting problems that the next generation of machines could solve.[16]
  54. The most difficult problem to solve in improving quantum computing and communications is the fragility of the quantum state of matter.[17]
  55. “As we push on the number of qubits, you’re able to explore a much more varied set of quantum circuits,” says Jerry Chow, the senior manager of the Experimental Quantum Computing Group at IBM.[17]
  56. To circumvent this problem and unlock the full potential of quantum computing, some researchers are working on adding error-correcting codes, which are already implemented in some classical computers.[17]
  57. Jerry Chow, IBM researcher in the Experimental Quantum Computing group, prepares for a quantum experiment.[17]
  58. Quantum computing could change the world.[18]
  59. Recently, Google claimed that it had achieved quantum supremacy – the first time a quantum computer has outperformed a traditional one.[18]
  60. A quantum computer can go down every path of the maze at once.[18]
  61. But in the realm of quantum computing, it means that you can move information around, even if it contains uncertainty.[18]
  62. Meanwhile, there is a lot of equipment to control the quantum computer.[19]
  63. Practically, that means that certain computations that can never be done on even the highest performing supercomputer will one day be computed on a quantum computer.[19]
  64. “The promise of quantum computing, ultimately, is that instead of getting close, you get exact,” Tony said.[19]
  65. The challenges in developing functioning quantum computing systems are manifold and daunting.[20]
  66. QuTech was created as an advanced research and education center for quantum computing by the Netherlands Organisation for Applied Research and the Delft University of Technology.[20]
  67. In addition to its collaboration with QuTech, Intel Labs is also working with other ecosystem members both on fundamental and system-level challenges on the entire quantum computing stack.[20]
  68. In fact, QuTech has already begun testing small-scale spin-qubit-based quantum computer systems.[20]
  69. Quantum computing, on the other hand, uses quantum bits or qubits.[21]
  70. According to the Institute for Quantum Computing at the University of Waterloo, the field of quantum computing started in the 1980s.[21]
  71. This latest demonstration of quantum computing’s potential from the USTC group is critical because it differs dramatically from Google’s approach.[22]
  72. But it quickly became apparent that building a universal photonic quantum computer was infeasible.[22]
  73. To even build a working quantum computer would require millions of lasers and other optical devices.[22]
  74. Boson sampling is a quantum computer that solves itself by being the distribution of photons.[22]
  75. In 2019, Google's research team made a major breakthrough when their quantum computer managed to solve a task far more quickly than the world's best supercomputer.[23]
  76. "We want to be sure that the quantum computer we are developing can help solve relevant problems early on.[23]
  77. The quantum computer completed the complex computation in 200 seconds.[24]
  78. Google's quantum computer consists of microscopic circuits of superconducting metal that entangle 53 qubits in a complex superposition state.[24]
  79. On paper, it's easy to show why a quantum computer could outperform traditional computers.[24]
  80. Classical computers have helped us unlock some mysteries we couldn't process with human power alone, but in the age of quantum computing, we may be able to take that power even further.[25]
  81. Understanding quantum systems could position you for research in true fault-tolerant quantum computing.[25]
  82. However, until that noise is reduced, quantum computing is still a significant factor in the next stage of cybersecurity and AI.[25]
  83. Other industries, such as healthcare and finance, are hoping to use quantum computing to untangle issues too complex for classical computing.[25]
  84. IBM , Google , Microsoft , Amazon , and other companies are investing heavily in developing large-scale quantum computing hardware and software.[26]
  85. Quantum computing and quantum communication could impact many sectors, including healthcare, energy, finance, security, and entertainment.[26]
  86. Hackers trying to copy quantum keys used for encrypting and transmitting messages would be foiled, even if they had access to a quantum computer, or other powerful resources.[26]
  87. The same can be said for a quantum computer compared to a classical computer.[26]
  88. A Quantum Computer is a processor whose function is based on the laws of quantum mechanics.[27]
  89. QUANTUM MECHANICS Quantum mechanics is the basis of Quantum Computing and refers to the scientific laws that affect the smallest dimension of nature: molecules, atoms and subatomic particles.[27]
  90. As the basis of Quantum Computing, Qubits can – in contrast to bits, which can only be represented by a zero or a one – be a zero, a one or both at the same time and form a so-called superposition.[27]
  91. That milestone, known as quantum supremacy, has been met only once before, in 2019 by Google’s quantum computer (SN: 10/23/19).[28]
  92. The quantum computer Jiuzhang manipulates light via a complex arrangement of optical devices (shown).[28]
  93. If operated with large numbers of photons and many channels, the quantum computer will produce a distribution of numbers that is too complex for a classical computer to calculate.[28]
  94. In contrast, Google’s quantum computer could be programmed to execute a variety of algorithms.[28]
  95. We think quantum computing will help us develop the innovations of tomorrow, including AI.[29]
  96. Quantum computing is a new paradigm that will play a big role in accelerating tasks for AI.[29]
  97. The past decade has seen explosive growth in research dedicated to quantum technologies such as quantum sensing, quantum communication, and quantum computing.[30]
  98. Quantum computing hardware requires extremely cold temperatures to operate and are therefore usually placed within a cryogenic dilution refrigerator.[30]
  99. The problem becomes clear when you look up a photo of a large quantum computer; all you see are massive cables for quantum computers going down.[30]
  100. Surprisingly, I am now doing something similar—I am studying how to solve problems on a quantum computer.[31]
  101. He managed to inspire a small number of people who started thinking: what would a quantum computer look like?[31]
  102. There are several tasks for which a quantum computer will be useful.[31]
  103. First of all, if we have a quantum computer, it will be useful for scientists for conducting virtual experiments.[31]
  104. Quantum computing may be viewed as the apex of quantum information processing algorithms.[32]
  105. The first paradigm is more common, and usually a reference to a “quantum computer” defaults to the gate-based concept.[32]
  106. Several other practical problems can be efficiently solved using quantum computing algorithms.[32]
  107. Programming such a quantum computer amounts to setting up a desired array of J i j final values.[32]
  108. An ultimate goal of quantum computing is to perform calculations beyond the reach of any classical computer.[33]
  109. This compression introduces a finite error rate ε so that the algorithms closely mimic the behavior of real quantum computing devices.[33]
  110. The quantum computer will feature Anyon’s Yukon generation superconducting quantum processor.[34]
  111. Quantum computing is expected to be a disruptive technology and is of strategic importance to many industries and government agencies.[34]
  112. Founded in 2014, Anyon Systems is the first Canadian company manufacturing gate-based quantum computing platform for universal quantum computation.[34]
  113. It seems plausible that it will always be possible to build classical computers that have more bits than the number of qubits in the largest quantum computer.[35]
  114. This means that a quantum computer can solve at least one problem much faster than any conventional supercomputer.[36]
  115. “This work pushes the needle in quantum computing for chemistry,” says quantum chemist and computer scientist Alán Aspuru-Guzik of the University of Toronto in Canada.[36]
  116. Any discussion of quantum computing feels like a quantum leap into a sci-fi realm.[37]
  117. So, computer innovators began to seek possible solutions at the atomic and subatomic level in a field known as quantum computing.[37]
  118. Industry leaders are racing to develop and launch a viable quantum computer and make it commercially available.[37]
  119. This year, Google stated publicly that it would produce a viable quantum computer in the next 5 years and added that they would reach “quantum supremacy” with a 50-qubit quantum computer.[37]
  120. How would you compare the effort in China in the area of quantum computing with that in other parts of the world, for example, in the United States?[38]
  121. It’s a billion dollars or so for quantum computing research.[38]
  122. They are trying to build a photonic quantum computer.[38]
  123. We want to go straight for a full error-corrected quantum computer.[38]
  124. With this new iteration, IonQ continues to lead the quantum computing field into the future.[39]
  125. no other quantum computer has been able to achieve, and even more importantly, we know how to continue making these systems much more powerful moving forward.[39]
  126. IonQ's unique approach to quantum computing is to start with nature: using individual atoms as the heart of our quantum processing units.[39]
  127. Quantum computing exploits the coherence and superposition properties of quantum systems to explore many possible computational paths in parallel.[40]
  128. In §2, the basic ideas of quantum computing are explained, and some of the various different models outlined.[40]
  129. There are many strands to the research into new types of computers, but one of the most established, and most promising in terms of the potential advantages, is quantum computing.[40]
  130. Quantum computing exploits two properties of quantum systems to access a fundamentally different logical operation from classical computing.[40]

소스

  1. 1.0 1.1 How a quantum computer works
  2. 2.0 2.1 2.2 2.3 What Is Quantum Computing?
  3. 3.0 3.1 3.2 3.3 Quantum computing: what is it, what can it do and how will it evolve?
  4. 4.0 4.1 4.2 4.3 What are quantum computers?
  5. 5.0 5.1 5.2 5.3 Quantum Computing (Stanford Encyclopedia of Philosophy)
  6. What is a quantum computer?
  7. 7.0 7.1 Explainer: What is a quantum computer?
  8. 8.0 8.1 8.2 8.3 Quantum computing 101 | Institute for Quantum Computing
  9. 9.0 9.1 9.2 9.3 The biggest flipping challenge in quantum computing
  10. 10.0 10.1 10.2 10.3 Quantum computer race intensifies as alternative technology gains steam
  11. 11.0 11.1 11.2 11.3 What is quantum computing and how does it work?
  12. 12.0 12.1 12.2 12.3 Quantum computing
  13. 13.0 13.1 Quantum for quants - Wall Street’s latest shiny new thing: quantum computing
  14. 14.0 14.1 14.2 14.3 Quantum computer | computer science
  15. 15.0 15.1 How Do Quantum Computers Work?
  16. 16.0 16.1 16.2 16.3 Simulating subatomic physics on a quantum computer
  17. 17.0 17.1 17.2 17.3 Quantum Computing: A Bubble Ready to Burst?
  18. 18.0 18.1 18.2 18.3 Quantum computing and quantum supremacy, explained
  19. 19.0 19.1 19.2 The World’s Highest Performing Quantum Computer is Here
  20. 20.0 20.1 20.2 20.3 Quantum Computing
  21. 21.0 21.1 Quantum Computing
  22. 22.0 22.1 22.2 22.3 Light-Based Quantum Computer Exceeds Fastest Classical Supercomputers
  23. 23.0 23.1 Tiny quantum computer solves real optimisation problem
  24. 24.0 24.1 24.2 Google's Quantum Computer Just Aced an 'Impossible' Test
  25. 25.0 25.1 25.2 25.3 Learn Quantum Computing with Online Courses and Classes
  26. 26.0 26.1 26.2 26.3 Are You Ready for the Quantum Computing Revolution?
  27. 27.0 27.1 27.2 Quantum Computing for Business
  28. 28.0 28.1 28.2 28.3 The new light-based quantum computer Jiuzhang has achieved quantum supremacy
  29. 29.0 29.1 Quantum – Google Research
  30. 30.0 30.1 30.2 Quantum Computer Hardware & Cables
  31. 31.0 31.1 31.2 31.3 What Can We Do with a Quantum Computer?
  32. 32.0 32.1 32.2 32.3 Quantum Computer - an overview
  33. 33.0 33.1 What Limits the Simulation of Quantum Computers?
  34. 34.0 34.1 34.2 Anyon Systems to Deliver a Quantum Computer to the Canadian Department of National Defense
  35. Quantum computer
  36. 36.0 36.1 Molecule’s electronic structure is simulated on a quantum computer – Physics World
  37. 37.0 37.1 37.2 37.3 15 Things Everyone Should Know About Quantum Computing
  38. 38.0 38.1 38.2 38.3 China gaining fast on US quantum computing lead
  39. 39.0 39.1 39.2 IonQ Unveils World's Most Powerful Quantum Computer
  40. 40.0 40.1 40.2 40.3 Quantum computing using continuous-time evolution

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