量子计算

目前在大规模并行计算模式方面主要存在两种新模式：量子计算模式和DNA计算模式。

Presently , two new computing paradigms are popular in large-scale parallel computation : quantum computing and DNA computing .

银河TS-1向量处理及其在量子计算中的应用

The Vector Processing of YH TS-1 and Its Application on Quantum Computing

量子计算与人工神经网络相结合的量子神经网络（QuantumNeuralNetworks，QNN）有可能成为未来信息处理的重要手段。

Quantum Neural Networks ( QNN ) is a promising area which integrates Artificial Neural Netowrk ( ANN ) with quantum computing .

当前实用的密码体制大都是计算安全的，但是随着计算能力的提高和密码分析技术的进步，特别是量子计算和DNA计算的迅猛发展，计算安全的密码体制面临着越来越大的挑战。

Nowadays many practical cryptosystems are computational security , whereas big challenges are emerging with the improvement of computing capacity and cryptanalysis technology , and especially the rapid development of quanta and DNA computation .

MgCl2/甲醇溶液的近红外光谱研究及量子计算

Study on MgCl_2 in Methanol by NIR Spectroscopy and Quantum Calculations

本文介绍了量子计算纠缠和量子比特的基本概念，系统阐述了几种主要的量子算法：Shor算法&大数质因子分解的量子算法；

In this thesis , several basic conceptions of quantum computation are introduced , such as entanglement , quantum bit .

随着量子计算、DNA计算、免疫计算、进化计算和神经计算等新型计算机制的兴起，传统的计算正扩展为自然计算，因为这些新计算机制的产生都由自然系统启发而来。

With burgeoning of new computing mechanisms such as quantum computation , DNA computation , immune computation , evolutionary computation and neural computation , etc. , traditional computing is being expanded as natural computation , because the new computing mechanisms are all inspired from some natural systems .

迄今为止，可用于量子计算实验的物理体系主要有：核自旋、电子自旋、光子、离子阱、超导Josephson结等。

Up to date , several different systems are available for the experimental realization of quantum computer : nuclear spins , electron spins , photons , trapped ions , superconductor Josephson junctions .

首先，作为本文提出的基于模型的人体跟踪的基础，本文在借鉴量子计算和量子进化算法（Quantum-InspiredEvolutionaryAlgorithm，QEA）思想的基础上，提出概率进化算法（ProbabilityEvolutionaryAlgorithm，PEA）。

Firstly , as the base of model-based human body tracking method in this paper , a novel evolutionary algorithm called Probability Evolutionary Algorithm ( PEA ) is proposed . PEA is inspired by the Quantum computation and Quantum-inspired Evolutionary Algorithm ( QEA ) .

要使集合完整并考虑普遍的量子计算，那么我们需要受控相位函数，CPhase（）。

To round out the set and allow for universal quantum computation , we need the Controlled Phase function , CPhase () .

应用量子计算方法分析了该量子神经元模型的量子逻辑运算功能，分析和实验证明单个量子神经元能实现经典神经元无法实现的XOR函数，并具有与两层前向神经网络相当的非线性映射能力。

Numerical and graphical results show that this single quantum neuron can perform XOR function unrealizable with a classical neuron and has the same computational power as the two-layer NN , it can be used to realize nonlinear mapping .

量子计算技术因其强大的计算能力，近十几年来，引起了人们极大的兴趣。

Quantum computer has interested people greatly for its remarkable computation capacity .

这里我们特别关注了如何将该框架应用在量子计算中。

Here , we focus on applying this framework to Quantum Computation .

几何量子计算和量子信息传输问题的研究

Geometric Quantum Computation and the Study of Problems of Quantum Information Transmission

近年来，量子计算已成为量子力学和计算机科学的交叉的活跃学科。

Quantum computation is an interdiscipline of Quantum Mechanics and computer science .

量子计算是量子力学与计算机理论的完美结合。

Quantum computation is the combination of quantum mechanics and computer science .

量子计算的表象无关性探讨

Discussion on Independence of Representative Space of Quantum Computing

量子计算是一种基于量子力学理论进行计算的新型计算模型。

Quantum computation is a new computation model based on quantum mechanics theory .

关于几何量子计算的一些研究

Some Research about Quantum Computation Based on Geometric Phase

原则上，在这个系统上可以进行通用的量子计算。

In principle , we can do universal quantum computation in this system .

评过量子计算的进展。

Recent progress in quantum computation is briefly reviewed .

实现容错量子计算的另一个途径是拓扑量子计算，但是常用的拓扑比特不能完成通用量子计算。

The other way to realize fault-tolerant quantum computation is topological quantum computation .

非绝热几何量子计算及拓扑量子门

Non-adiabatic geometric quantum computation and topological quantum gates

利用量子计算网络实现量子远距传态

Realization of Quantum Teleportation by Quantum Computing Network

用正交态方法实现非绝热几何量子计算

Non-adiabatic Geometric QC Implemented with Orthogonal State Method

细胞骨架微管中一种可能的量子计算

A Possible Quantum Computation in Cytoskeletal Microtubule

无消相干子空间的几何量子计算方案

Geometric Quantum Computation in a Decoherence-Free Subspace

中国科研团队取得量子计算优势，计算能力取得重大突破。

A Chinese research team has achieved quantum computational advantage , a significant computing breakthrough .

贝尔纠缠现在被用于多个实际应用，如量子计算和密码学。

Bell entanglement is now harnessed in practical applications such as quantum computing and cryptography .

这是一个细微的区别，但却是量子计算中的一个重要区别。

It 's a subtle distinction , but one that is critical in quantum computing .