量子并行计算

  • 网络quantum parallelism;quantum parallel computing;quantum parallel computation
量子并行计算量子并行计算
  1. 比如,人们利用量子态具有相干叠加特性构造出量子并行计算。它可以有效的解决如大数的因式分解,复杂量子系统的模拟等问题。

    Such as , based on the correlated superposition of quantum states , scientists have developed quantum parallelism arithmetic , which could be used to resolve efficiently some hard problems such as factorization of large numbers and the simulation of complicated quantum systems .

  2. 量子神经网络是量子计算与人工神经网络(ANN)相结合的产物,由于利用了量子并行计算和量子纠缠等特性从而克服了传统人工神经网络的固有缺点。

    Quantum Neural Networks is the combination of quantum computing and Artificial Neural Network ( ANN ) . Taking advantages of the properties of quantum mechanics such as quantum parallelism and entanglement .

  3. 量子并行计算是通过幺正变换对量子比特上所有信息实施同时同样操作的方法得到函数各个自变量对应的函数值的算法。

    Quantum parallel computing is algorithm to get function value corresponding to any variables of a function by unitary operations on quantum bits leading to information processing simultaneously on the same operation in same way .

  4. 多用户检测技术的最优解在常规条件下是一个NP难解问题,利用量子态的并行计算特性以及量子态检测等理论,量子多用户检测技术能够有效地获得多用户检测的最优解。

    The optimal solution for the conventional multi-user detection is a NP hard problem . The quantum multi-user detection ( QMUD ) which based on quantum mechanics can solve this problem efficiently .

  5. 机群系统中实现量子化学从头算并行计算的研究

    Study on Parallelism of Quantum Chemistry Ab Initio Calculation in PC Cluster

  6. 核磁共振量子计算机与并行量子计算

    Nuclear magnetic resonance quantum computer and parallel quantum computing

  7. 量子计算机因其并行计算和量子模拟的巨大速度优势,有着非常诱人的应用前景。

    Quantum computer is promising for the great speed of its parallel computation and quantum simulation .

  8. 其中,量子计算机的优越性体现在量子并行计算上,从而可以进行超快速计算和模拟量子系统,并能解决经典计算机无法解决的问题。

    The quantum computer can perform ultra-fast calculation , simulate quantum system , and solve problems that cannot be solved by classical digital computer .

  9. 用矩阵表示量子信息中的量子态便于进行量子并行计算。

    Matrix denotation of quantum state is convenient for quantum parallel computation .

  10. 利用量子叠加性和相干性,可以实现量子计算机的并行计算,大大提高量子计算机的效率;隐形传态和量子态的远程制备等量子技术都是利用量子纠缠态作为通道实现的。

    Using quantum superposition and coherence , one can realize the parallel computing of quantum computer , so the efficiency of quantum computer has greatly enhanced .

  11. 本文简要地介绍量子计算的一些基本概念:量子纠缠、量子位、量子寄存器、量子并行计算和量子纠错。

    In this paper we briefly introduce some basic concepts of quantum computing which include quantum entanglement , quantum bit , quantum register , quantum parallel computing and quantum error correction .