1) spiral wave dynamics
旋波动力学
1.
Objective: To study the spiral wave dynamics in controlling ventricular fibrillation.
方法:利用旋波动力学的研究方法,对二维心脏系统施加周期驱动与有效驱动数值模拟心室颤动的控制和消除。
2) wave mechanics
波动力学
1.
By the analysis of wave mechanics of typical percussive drilling system of rock, characteristic parameter a, which describes wave dynamics and structure of the percussive drill system, has been presented.
通过对冲击凿岩典型系统的波动力学分析,提出了反映冲击凿岩机具波动力学和结构特征的参数α,继而确定冲击凿岩机具的动力学特征参数α和运动学特征参数τ,实现了活塞弹性动力学与刚体运动学的融合,为冲击凿岩机具的概念设计提供了较完整的方法。
2.
By using wave mechanics, the process of impact driving pile is analyzed,and a mechanics mode of impact driving system which consists of hammer spring cup and pile is established.
应用波动力学分析了冲击沉桩过程,建立了由冲锤、桩帽和桩组成的冲击沉桩系统的力学模型,研究了冲锤重量、桩帽刚度和桩波阻抗对效率的影响,在此基础上,提出了冲锤、桩帽和桩的最佳方案。
3.
After studying Schredinger equation,we find that relativity is the inner natural property of wave mechanics.
通过对Schredinger方程的研究,认为相对论性是波动力学的内禀属性。
3) racemization kinetics
消旋动力学
4) Gyrokinetics
回旋动力学
5) rotating dynamics
旋转动力学
1.
Based on rotating dynamics theory for computational creativity, thought inertia space model is proposed, including its constructing methods and properties, which posits that creativity can be reached through topology extension of thought inertia space by using inventive techniques such as substance field analysis, transformation creativity and combination creativity, etc.
根据思维的旋转动力学理论提出了思维惯性空间模型,包括惯性空间的构造及其性质,指出了创造就是通过物场分析、转换创造、组合创造等发明方法实现对惯性空间的拓扑扩展。
2.
Based on dialectics thinking and psychology theory, rotating dynamics is a newly created framework for computational creativity using differential topology.
旋转动力学理论是以辨证逻辑和心理学理论为指导 ,微分拓扑为工具建立起来的创新计算的统一理论框架 。
3.
, rotating dynamics provides an unifying framework for computational creativity by employing differential topology.
旋转动力学理论是以辨证思维和心理学理论为指导 ,微分拓扑为工具建立起来的创新计算的统一理论框架 。
6) vortex dynamics
涡旋动力学
1.
The hypothesis of vortex dynamics is proposed for explaining the peculiarities of excess heat and anomalous nucleus phenomena in .
提出了涡旋动力学理论解释电化学放电过程中的异常现象———过剩热和非平衡系统中的异常核现象。
2.
Since the discovery of high-Tc superconductors, vortex dynamics, which is an important key to understand superconductivity, becomes a central problem, and especially the time-dependent Ginzburg-Landau (TDGL) model that describes the dynamical properties of superconductors has been a subject of theoretical and experimental work.
自从高温超导体发现以来,涡旋动力学成为研究的中心问题,因为它是理解超导电性的重要关键之一。
3.
The hypothesis of vortex dynamics is proposed for explaining the peculiarities of excess heat and anomalous nucleus phenomena in the non-equ.
提出了涡旋动力学理论解释电化学放电过程中的异常现象——过剩热和非平衡系统中的异常核现象。
补充资料:波动力学
| 波动力学 wave mechanics 根据微观粒子的波动性建立起来的用波动方程描述微观粒子运动规律的理论,量子力学理论的一种表述形式。1924 年 ,L.V.德布罗意提出微观粒子具有波动性的假设 。1926年,E.薛定谔在此基础上提出微观粒子运动满足的波动方程,用于解决氢原子问题获得成功,后来用于其他问题,并发展了完善的近似计算方法。波动力学使用比较熟悉的波动语言和偏微分方程,比较适合于初学者,在量子理论的基本应用中最常使用的也是这种形式。 |
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参考词条