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==Connection to tent map==
==与帐篷映射的关系==
[[File:Lorenz_Map.png|thumb|A recreation of Lorenz's results created on [[Mathematica]]. Points above the red line correspond to the system switching lobes.|upright=1.3]]
[[File:Lorenz_Map.png|thumb|A recreation of Lorenz's results created on [[Mathematica]]. Points above the red line correspond to the system switching lobes.|upright=1.3]]
In Figure 4 of his paper,<ref name=lorenz /> Lorenz plotted the relative maximum value in the z direction achieved by the system against the previous relative maximum in the z direction. This procedure later became known as a Lorenz map (not to be confused with a [[Poincaré plot]], which plots the intersections of a trajectory with a prescribed surface). The resulting plot has a shape very similar to the [[tent map]]. Lorenz also found that when the maximum z value is above a certain cut-off, the system will switch to the next lobe. Combining this with the chaos known to be exhibited by the tent map, he showed that the system switches between the two lobes chaotically.
In Figure 4 of his paper,<ref name=lorenz /> Lorenz plotted the relative maximum value in the z direction achieved by the system against the previous relative maximum in the z direction. This procedure later became known as a Lorenz map (not to be confused with a [[Poincaré plot]], which plots the intersections of a trajectory with a prescribed surface). The resulting plot has a shape very similar to the [[tent map]]. Lorenz also found that when the maximum z value is above a certain cut-off, the system will switch to the next lobe. Combining this with the chaos known to be exhibited by the tent map, he showed that the system switches between the two lobes chaotically.
==Simulations==
在论文的图4中,<ref name=lorenz />洛伦兹将系统在z方向上取得的相对最大值与之前在z方向上的相对最大值作了对比。通过这一步骤我们得到了洛伦兹图(不要与[[彭加莱图]](Poincaré plot)相混淆,彭加莱图绘制的是轨迹与规定曲面的交点)。这一图型的形状与[[帐篷映射]](tent map)非常相似。洛伦兹还发现,当Z的最大值值高于某个截断时,系统就会切换到下一个波段(lobe)。通过结合这一点和帐篷映射所表现出的混沌性,洛伦兹阐明了这一系统在两个波段(lobe)之间地切换是混沌的。
===MATLAB simulation===
==模拟==
===使用 MATLAB 进行模拟===
<syntaxhighlight lang="matlab">
<syntaxhighlight lang="matlab">
% Solve over time interval [0,100] with initial conditions [1,1,1]
% Solve over time interval [0,100] with initial conditions [1,1,1]
</syntaxhighlight>
</syntaxhighlight>
=== Mathematica simulation ===
=== 使用 Mathematica 进行模拟===
Standard way:
Standard way:
</syntaxhighlight>
</syntaxhighlight>
=== Python simulation ===
=== 使用 Python 进行模拟 ===
<syntaxhighlight lang="python">
<syntaxhighlight lang="python">
import numpy as np
import numpy as np
== Derivation of the Lorenz equations as a model for atmospheric convection ==
== Derivation of the Lorenz equations as a model for atmospheric convection ==
== 将洛伦兹方程的推导应用到大气对流模型 ==
The Lorenz equations are derived from the [[Boussinesq approximation (buoyancy)|Oberbeck–Boussinesq approximation]] to the equations describing fluid circulation in a shallow layer of fluid, heated uniformly from below and cooled uniformly from above.<ref name="lorenz"/> This fluid circulation is known as [[Rayleigh–Bénard convection]]. The fluid is assumed to circulate in two dimensions (vertical and horizontal) with periodic rectangular boundary conditions.
The Lorenz equations are derived from the [[Boussinesq approximation (buoyancy)|Oberbeck–Boussinesq approximation]] to the equations describing fluid circulation in a shallow layer of fluid, heated uniformly from below and cooled uniformly from above.<ref name="lorenz"/> This fluid circulation is known as [[Rayleigh–Bénard convection]]. The fluid is assumed to circulate in two dimensions (vertical and horizontal) with periodic rectangular boundary conditions.
洛伦兹方程由描述流体浅层中流体循环的[[布辛涅斯克近似|Oberbeck–Boussinesq approximation]]推导而来,方程中的流体处在上层被加热而下层被冷却的状态。<ref name="lorenz"/>这一类流体循环又被称为[[瑞利-贝纳德热对流]](Rayleigh–Bénard convection)。我们通常假设这类流体在水平和垂直两个方向循环,并具有矩形边界条件。
The partial differential equations modeling the system's [[stream function]] and temperature are subjected to a spectral [[Galerkin method|Galerkin approximation]]: the hydrodynamic fields are expanded in Fourier series, which are then severely truncated to a single term for the stream function and two terms for the temperature. This reduces the model equations to a set of three coupled, nonlinear ordinary differential equations. A detailed derivation may be found, for example, in nonlinear dynamics texts.<ref>{{harvtxt|Hilborn|2000}}, Appendix C; {{harvtxt|Bergé|Pomeau|Vidal|1984}}, Appendix D</ref> The Lorenz system is a reduced version of a larger system studied earlier by Barry Saltzman.<ref>{{harvtxt|Saltzman|1962}}</ref>
The partial differential equations modeling the system's [[stream function]] and temperature are subjected to a spectral [[Galerkin method|Galerkin approximation]]: the hydrodynamic fields are expanded in Fourier series, which are then severely truncated to a single term for the stream function and two terms for the temperature. This reduces the model equations to a set of three coupled, nonlinear ordinary differential equations. A detailed derivation may be found, for example, in nonlinear dynamics texts.<ref>{{harvtxt|Hilborn|2000}}, Appendix C; {{harvtxt|Bergé|Pomeau|Vidal|1984}}, Appendix D</ref> The Lorenz system is a reduced version of a larger system studied earlier by Barry Saltzman.<ref>{{harvtxt|Saltzman|1962}}</ref>
对系统的[[流函数]](stream function)和温度建模的偏微分方程隶属于谱[[加勒金法(Galerkin method)|Galerkin approximation]]:水动力场以傅里叶级数展开,然后将其严格截断为一个流函数项和两个温度项。这就把模型方程简化为一系列三个耦合的、非线性的常微分方程。详细的推导可以在非线性动力学相关的文献中找到。<ref>{{harvtxt|Hilborn|2000}}, Appendix C; {{harvtxt|Bergé|Pomeau|Vidal|1984}}, Appendix D</ref> The Lorenz system is a reduced version of a larger system studied earlier by Barry Saltzman.<ref>{{harvtxt|Saltzman|1962}}</ref>
== Resolution of Smale's 14th problem ==
== Resolution of Smale's 14th problem ==