It is significant to the quantum information processing based on the geometric phase.
该结果对基于几何相位的容错量子信息处理具有非常重要的意义。
Quantum logic gate is a functional component which realizes solid state quantum information processing.
量子逻辑门是实现量子信息处理的功能器件。
Quantum information processing with continuous variables is an important part in quantum information science.
连续变量量子信息是量子信息科学研究的一个重要内容。
The result reveals the profound nature of the entanglement and should have significant implications for quantum information processing.
我们的结果揭示了纠缠的深刻性质,也将在量子信息处理中有着重要的作用。
The interaction between quantum systems and environment brings great difficulties to the implementation of quantum information processing.
然而,系统与环境的相互作用给量子信息处理的具体实现带来了巨大的困难。
Particularly, this system can be used to generate a class of W states, which have a potential application in quantum information processing.
尤其是在一定条件下,能利用该系统能制备一类W态,这类态在量子信息处理中有潜在的应用。
In order to understand the quantum information processing in QKD system, complete quantum mechanics method was employed to describe QKD system.
因为QKD系统是对单量子态的操作,因此QKD系统本质上是量子力学系统。
Quantum entanglement is an important physical resource, which can be applied significantly in the quantum information processing and computation science.
量子纠缠是一种重要的物理资源,在量子信息和计算科学中有重要应用。
This will affect quantum information processing, and thus cause the loss of quantum information. Therefore, we need to investigate quantum communication via mixed states.
也就是说,消相干和解纠缠在量子信息处理过程中是不可避免的,这将使纯的量子通道退化为混态量子通道。
In this thesis, we focus our research on applying the multiparticle entanglement in quantum information processing, assisted by local operation and classical communication.
本论文重点研究了一些经典通信和局域操作辅助下多体纠缠对处理量子信息的作用。
Thus exploring the robustness features of quantum information processing system in presence of various imperfections will be very helpful to design fault-tolerant quantum information processor.
因此分析量子信息处理系统在各种干扰下的演化规律,研究干扰对量子计算鲁棒性的影响,将非常有助于设计高可靠性的容错量子计算系统。
The computers of tomorrow could be quantum not classical, using the quantum world's strange properties to vastly increase memory and speed up information processing.
在未来世界,量子计算机可能会取代当代的电脑,借助于量子世界中的诸多奇性,未来计算机的容量将急剧膨胀,其信息处理的速度也会突飞猛进。
Combining the‘‘quantumness’’ of light and matter in such experiments also leads to promising advances in the processing of quantum information.
在这样的实验中结合光的量子性能够仔细研究有关量子力学的信息。
By directly linking the motions of two physically separated atoms, the technique has the potential to simplify information processing in future quantum computers and simulations.
这一技术简化了信息处理过程,可用于未来的量子计算机、模拟技术和量子网络中。相关研究发表在2月23日的《自然》杂志上。
Such an approach could reconcile relativity and quantum theories, with the former being how information processing creates space-time, and the latter how it creates energy and matter.
这种方法可以使相对论和量子理论相和谐,前者可以解释信息处理过程怎样创造空间——时间,后者可以解释信息处理怎样创造能量和物质。
So, we develop the photon coincidence instrument using by modern circuit and computer, it is very important measure instrument in common use for quantum communication and information processing.
本文研制的光子符合仪就是利用现代电路和计算机技术实现的量子通信和信息处理中最常用、最重要的测试仪器。
However, whether the traditional computer or the future quantum computer, both need the certain space to store the processing information.
然而不管是传统的计算机还是未来的量子计算机,都需要一定的存储空间,用来存储有待处理的信息。
Quantum neural networks (QNN) Integrates the characteristics of artificial neural networks by quantum neuron computing, and becomes a promising field in information processing.
量子神经计算是传统神经计算与量子计算相结合的产物,它已成为新的信息处理技术之一。
Based on basic principles of quantum mechanics and with quantum states as information carriers, storage, transmission and processing capabilities can be accomplished.
量子信息科学以量子力学基本原理为依据,以量子态为信息载体,来完成信息的存储,处理和传输。
Based on basic principles of quantum mechanics and with quantum states as information carriers, storage, transmission and processing capabilities can be accomplished.
量子信息科学以量子力学基本原理为依据,以量子态为信息载体,来完成信息的存储,处理和传输。
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