量子电路

  • 网络quantum circuit
量子电路量子电路
  1. 量子电路可逆逻辑综合的研究及进展

    Reversible Logic Synthesis of Quantum Circuit : Survey and Progress

  2. 量子电路容错方法的研究。

    ( 2 ) Research on the fault-tolerant method for quantum circuit .

  3. 本文阐述的重点是量子电路的可逆逻辑综合问题。

    This paper expatiates on synthesis of quantum reversible logic circuits .

  4. 超导量子电路是实现量子计算和量子信息传输的重要途径之一。

    Superconductivity quantum circuit is one of the most important ways for realizing quantum computation and quantum information .

  5. 通过实验验证,上述两个电路模型能够很好的模拟其分别对应的量子电路,而且具有很高的效率。

    Experimental results show , the two circuit models can simulate the corresponding quantum circuit , and high efficiency .

  6. 本文介绍了现在对此方面的研究现状和成果,探索了量子电路综合方法的规律,并提出一种将遗传算法应用于量子可逆逻辑电路综合的新方法。

    This paper introduces the current situation and production of the research of synthesis of quantum reversible logic circuits and its rules . We present a new method to synthesize quantum reversible logic circuits based on genetic algorithm .

  7. 为了提高量子逻辑电路的优化技术,减小量子逻辑电路的代价,对现有的模板技术进行了研究与分析,发现Maslov等人的模板并不完整,体现在模板控制线的寻找不完全。

    To improve the technique of optimizing quantum logical circuit and reduce the cost of quantum logical circuit , the current template technology is analyzed . It is found that Maslov 's templates are incomplete for their control lines are incomplete .

  8. 模板技术在量子逻辑电路优化中的应用

    Application of template technique in optimizing quantum logical circuit

  9. 同时给出了利用该方法优化量子逻辑电路的算法。

    Based on this method , an algorithm is provided to optimize quantum circuit .

  10. 量子逻辑电路中控制点失效错误的定位

    Fault Localization for Broken Control in Quantum Circuits

  11. 该仿真平台包括量子门电路的设计仿真模块、量子密钥分配仿真模块、效果演示模块,可用于量子密钥通信和量子密钥算法改进的综合仿真。

    This simulation platform includes the design of quantum gate circuit simulation module , quantum key distribution simulation module and the effect of presentation modules .

  12. 基于遗传模拟退火法的量子细胞自动机电路仿真

    Simulation of Quantum Cellular Automaton Circuits Based on Genetic Simulated Annealing Algorithm

  13. 基于遗传算法的量子可逆逻辑电路综合方法研究

    Research of the Quantum Reversible Logic Circuits Synthesis Based on Genetic Algorithm

  14. 量子可逆逻辑电路综合的快速算法研究

    A Fast Algorithm for Synthesis of Quantum Reversible Logic Circuits

  15. 此外,通过适当地编码,仅仅海森堡相互作用就足以实现任何量子计算逻辑电路。

    In addition , by proper encoding , the Heisenberg interaction alone can support universal quantum computation .

  16. 其次,再配合我们建立的量子力学等效电路模型,来研究半导体元件中载子在量子井的运动情形。

    And the second , we use the equivalent circuit model of semiconductor device with quantum mechanics to observe the charge distribution in the quantum well .

  17. 广义特征值问题在科学计算与工程应用领域有着广泛的应用,例如,结构动态分析、结构振动、电子结构计算、量子化学、电路网络、化学反应、宏观经济平衡等。

    Symmetric generalized eigenvalue problems arise in many science computing and engineering applications , such as dynamic analysis of structures , structural vibration , electronic structure calculations , quantum chemistry , circuit network , chemical reaction , macro-economical balance .

  18. 研究表明,单电子环形存储器单元电路利用量子点环状电路结构形式,由外接输入电压控制各岛上的电荷,能够得到存储器的“0”和“1”状态。

    It is shown that the two states ( '0'and '1 ' ) of single-electron ring memory , which has a cyclic array of quantum dots , can be implemented by input voltage controlling the charges on the islands .

  19. 基于RT量子器件的数字电路设计

    Digital Circuits Design Based on RT Quantum Devices

  20. 给出一个新的量子阱激光器等效电路模型,由量子阱激光器单模速率方程推导得到并在电路模拟程序SPICE中完成。

    A simple equivalent circuit model of quantum well laser ( QW LD ) which is derived by QW rate equations and is accomplished in the circuit simulation program SPICE .

  21. 本文介绍了快速单磁通量子(RSFQ)电路的基本原理和部分逻辑门电路工作原理及其设计注意点。

    In this paper , the principles and characteristics of rapid single flux quantum ( RSFQ ) circuits are discussed .

  22. 快速单磁通量子计数器及其逻辑电路

    Rapid single flux quantum counter and it ′ s logic circuits

  23. 一个简单的量子阱激光器等效电路模型

    A Simple Equivalent Circuit Model of QWLD

  24. 量子态统计测量电路探讨

    Circuits for statistical measurement of quantum states

  25. 虚拟仪器在射频超导量子干涉仪控制电路中的应用

    RF SQUID virtual instrument controlling system

  26. 近些年来,纳米技术的进步能够将一个量子点嵌入到电路当中去。

    In recent years , advances in nanotechnology can embed a quantum dot into the circuit .

  27. 同时特别关注了以往未加深入研究的耦合部分的量子涨落。当电路的参数不随时间变化时,也可以有压缩产生。

    Squeezing can be generated as the parameters of the circuit or inductances and capacitances change with time and time independent .

  28. 结果表明,介观无损耗传输线中电流的量子涨落不仅与电路的参数有关,还与传输线所处的环境温度有关。

    It is shown that the quantum fluctuations depend on not only the parameters of the transmission line but also the environmental temperature T.

  29. 结果表明,支路电流电压的量子涨落不仅与电路器件的参数有关,而且和激发量子数、压缩因子及压缩角有关,并随时间衰减。

    The result shows that the quantum fluctuations of the current and voltage of each branch are related with not only parameter of the circuit element , but also quantum number of excitation , squeezed coefficients and squeezed angle . These fluctuations decay with time because of damped resistance .

  30. 在文章最后介绍了实验中实现量子门和量子逻辑电路的一些方法。

    At the end , we introduced some means in experimentations to realize quantum gates and quantum logic circuits .