中国科技大学研制成功世界上第一台量子计算机

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链接:http://www.tianya.cn/publicforum/content/itinfo/75561/1/0/1.shtml
      
   研究成果发表在2007年12月19日出版的国际权威物理学最权威的期刊《 Physical Review Letters》上,标志着我国光学量子计算机研究达到了国际领先水平。
November 2007, to be published in Physical Review Letters
  
  Demonstration of a compiled version of Shor's quantum factoring algorithm using photonic qubits
  
  Chao-Yang Lu, Daniel E. Browne, Tao Yang, and Jian-Wei Pan
  
  We report an experimental demonstration of a complied version of Shor's algorithm using four photonic qubits. We choose the simplest instance of this algorithm, that is, factorization of $N=15$ in the case that the period $r=2$ and exploit a simplified linear optical network to coherently implement the quantum circuits of the modular exponential execution and semi-classical quantum Fourier transformation. During this computation, genuine multiparticle entanglement is observed which well supports its quantum nature. This experiment represents an essential step toward full realization of Shor's algorithm and scalable linear optics quantum computation.
  
  2007 The American Physical Society.
  
  中国科技大学的这篇prl 似乎很有分量。两个月前,这篇论文还仅仅是预印本的时候,《新科学家》(new scientist)就报道了
  
  
http://technology.newscientist.com/article/mg19526216.700
  
  Quantum threat to our secret data
  
  * 13 September 2007
  * Saswato Das
  * Magazine issue 2621
  
  IT MIGHT seem like an esoteric achievement of interest to only a handful of computer scientists, but the advent of quantum computers that can run a routine called Shor's algorithm could have profound consequences. It means the most dangerous threat posed by quantum computing - the ability to break the codes that protect our banking, business and e-commerce data - is now a step nearer reality.
  
  Adding to the worry is the fact that this feat has been performed by not one but two research groups, independently of each other. One team is led by Andrew White at the University of Queensland in Brisbane, Australia, and the other by Chao-Yang Lu (USTC的,第一作者;潘建伟是通信作者) of the University of Science and Technology of China, in Hefei. Both groups have built rudimentary laser-based quantum
  computers that can implement Shor's algorithm - a mathematical routine capable of defeating today's most common encryption ...
  
  
  潘建伟的论文被PRL接收后,还没有正式发表,德国的《创新报导》又发表了评论:
  
  
http://www.innovations-report.de/html/berichte/physik_astronomie/bericht-99247.html
  
  A quantum computer breakthrough and dark matter stars
  (30.11.2007)
  Highlights in this issue: A quantum computer breakthrough and dark matter stars.
  
  Anzeige
  Quantum Computer Breakthrough
  
  Chao-Yang Lu, Daniel E. Browne, Tao Yang, and Jian-Wei Pan
  Physical Review Letters (forthcoming) &
  
  B. P. Lanyon, T. J. Weinhold, N. K. Langford, M. Barbieri, D. F. V. James , A. Gilchrist, and A. G. White
  Physical Review Letters (forthcoming)
  
  Two research groups have independently managed to experimentally solve a mathematical problem with light-based quantum computers. The simultaneous achievements appear to be the first experimental demonstrations of true (though rudimentary) quantum mechanical computations. Both groups manipulated quantum mechanically entangled photons to calculate the prime factors of the number 15.
  
  Although the physicists could have gotten the answer to the problem much more easily by querying an average elementary school child, the method both groups used involved a quantum mechanical approach commonly known as Shor's algorithm. Previous theoretical work has shown that the algorithm could potentially crack cryptographic codes that are practically unbreakable with non-quantum mechanical (classical) computers.
  
  While there's no great need to factor numbers as small as 15, the research demonstrates that quantum computation is feasible with existing technology and could in principle be scaled up to tackle problems that would take longer than the age of the universe to solve with any classical computer, but would require only minutes on a quantum computer.
  
  In addition to factoring large numbers and solving other challenging mathematical problems, quantum computers based on the work of these two groups could help model quantum mechanical problems in physics and chemistry (se
http://xxx.lanl.gov/ftp/arxiv/papers/0710/0710.0278.pdf for an example of a quantum simulator experiment by C.-Y. Lu et al.), and lead to ultra high speed searching algorithms.
  
  Chao-Yang Lu (USTC的,第一作者;潘建伟是通信作者)and his group are currently expanding on their work by trying to manipulate larger numbers of quantum bits. In the long run, they plan to add quantum memory to their quantum computers, which could further increase the number of photons they can control. In addition, because the loss of photons is a huge problem for light-based quantum computation, they are working on some basic quantum codes that can protect the quantum information from photon loss error. These sorts of issues are crucial in the effort to scale up photonic quantum computation. - JR
  
  澳大利亚的一个小组和USTC同时实现了这一伟大的突破。
  
  重要的句子:
  Both groups have built rudimentary laser-based quantum
  computers that can implement Shor's algorithm - a mathematical routine capable of defeating today's most common encryption .
链接:http://www.tianya.cn/publicforum/content/itinfo/75561/1/0/1.shtml
      
   研究成果发表在2007年12月19日出版的国际权威物理学最权威的期刊《 Physical Review Letters》上,标志着我国光学量子计算机研究达到了国际领先水平。
November 2007, to be published in Physical Review Letters
  
  Demonstration of a compiled version of Shor's quantum factoring algorithm using photonic qubits
  
  Chao-Yang Lu, Daniel E. Browne, Tao Yang, and Jian-Wei Pan
  
  We report an experimental demonstration of a complied version of Shor's algorithm using four photonic qubits. We choose the simplest instance of this algorithm, that is, factorization of $N=15$ in the case that the period $r=2$ and exploit a simplified linear optical network to coherently implement the quantum circuits of the modular exponential execution and semi-classical quantum Fourier transformation. During this computation, genuine multiparticle entanglement is observed which well supports its quantum nature. This experiment represents an essential step toward full realization of Shor's algorithm and scalable linear optics quantum computation.
  
  2007 The American Physical Society.
  
  中国科技大学的这篇prl 似乎很有分量。两个月前,这篇论文还仅仅是预印本的时候,《新科学家》(new scientist)就报道了
  
  
http://technology.newscientist.com/article/mg19526216.700
  
  Quantum threat to our secret data
  
  * 13 September 2007
  * Saswato Das
  * Magazine issue 2621
  
  IT MIGHT seem like an esoteric achievement of interest to only a handful of computer scientists, but the advent of quantum computers that can run a routine called Shor's algorithm could have profound consequences. It means the most dangerous threat posed by quantum computing - the ability to break the codes that protect our banking, business and e-commerce data - is now a step nearer reality.
  
  Adding to the worry is the fact that this feat has been performed by not one but two research groups, independently of each other. One team is led by Andrew White at the University of Queensland in Brisbane, Australia, and the other by Chao-Yang Lu (USTC的,第一作者;潘建伟是通信作者) of the University of Science and Technology of China, in Hefei. Both groups have built rudimentary laser-based quantum
  computers that can implement Shor's algorithm - a mathematical routine capable of defeating today's most common encryption ...
  
  
  潘建伟的论文被PRL接收后,还没有正式发表,德国的《创新报导》又发表了评论:
  
  
http://www.innovations-report.de/html/berichte/physik_astronomie/bericht-99247.html
  
  A quantum computer breakthrough and dark matter stars
  (30.11.2007)
  Highlights in this issue: A quantum computer breakthrough and dark matter stars.
  
  Anzeige
  Quantum Computer Breakthrough
  
  Chao-Yang Lu, Daniel E. Browne, Tao Yang, and Jian-Wei Pan
  Physical Review Letters (forthcoming) &
  
  B. P. Lanyon, T. J. Weinhold, N. K. Langford, M. Barbieri, D. F. V. James , A. Gilchrist, and A. G. White
  Physical Review Letters (forthcoming)
  
  Two research groups have independently managed to experimentally solve a mathematical problem with light-based quantum computers. The simultaneous achievements appear to be the first experimental demonstrations of true (though rudimentary) quantum mechanical computations. Both groups manipulated quantum mechanically entangled photons to calculate the prime factors of the number 15.
  
  Although the physicists could have gotten the answer to the problem much more easily by querying an average elementary school child, the method both groups used involved a quantum mechanical approach commonly known as Shor's algorithm. Previous theoretical work has shown that the algorithm could potentially crack cryptographic codes that are practically unbreakable with non-quantum mechanical (classical) computers.
  
  While there's no great need to factor numbers as small as 15, the research demonstrates that quantum computation is feasible with existing technology and could in principle be scaled up to tackle problems that would take longer than the age of the universe to solve with any classical computer, but would require only minutes on a quantum computer.
  
  In addition to factoring large numbers and solving other challenging mathematical problems, quantum computers based on the work of these two groups could help model quantum mechanical problems in physics and chemistry (se
http://xxx.lanl.gov/ftp/arxiv/papers/0710/0710.0278.pdf for an example of a quantum simulator experiment by C.-Y. Lu et al.), and lead to ultra high speed searching algorithms.
  
  Chao-Yang Lu (USTC的,第一作者;潘建伟是通信作者)and his group are currently expanding on their work by trying to manipulate larger numbers of quantum bits. In the long run, they plan to add quantum memory to their quantum computers, which could further increase the number of photons they can control. In addition, because the loss of photons is a huge problem for light-based quantum computation, they are working on some basic quantum codes that can protect the quantum information from photon loss error. These sorts of issues are crucial in the effort to scale up photonic quantum computation. - JR
  
  澳大利亚的一个小组和USTC同时实现了这一伟大的突破。
  
  重要的句子:
  Both groups have built rudimentary laser-based quantum
  computers that can implement Shor's algorithm - a mathematical routine capable of defeating today's most common encryption .
回复 1# 十月放歌

2007年的旧闻:D
又是旧闻,只闻楼梯响,不见人下来。