xianxinghe-Sxingjiajiansu

快速HLS彩色空间变换方法.caj CAJView打开(Fast HLS color space conversion)

专家控制学习的基础，一个简洁易懂的PID专家控制(Exper PID Controller)

说明：  边缘检测的新方法，与传统边缘检测方法的比较(new edge detection method with the traditional edge detection method of comparison)

For getting Mfcc coefficients

小车避障 模糊控制 simulink仿真(The car obstacle avoidance fuzzy control simulink simulation)

基于随机共振的弱信号检测，sr为龙格库塔方法解方程，rs为检测的主程序(Based on stochastic resonance in weak signal detection, sr for the Runge-Kutta method to solve the equation, rs for the detection of the main program)

简单介绍脉冲压缩前后的对比，数据清晰明了，代码简单易懂，使读者能够直观读懂脉冲压缩体制(Compare before and after a brief pulse compression, data clarity, the code is simple to understand, so that readers can intuitively understand the pulse compression system)

运用差分进化算法（DE）优化分数阶pid控制器(Use of differential evolution algorithm (DE) optimization of fractional order pid controller)

这是一个100个MATLAB 实例程序，也是从网上搜索到的，对大家有用才好。(This is a 100 MATLAB Examples of procedures, but also from the Internet to search for useful everyone to do.)

这是一个简单的FFT为无电位1 +1 +1 Ð 薛定谔方程的光束传播方法。如果该软件灵活，允许引入的术语（如果是极少数需要包括色散效应高阶导数）。例如，如果一个人渴望解决的一个方程的形式： （四/ dz的+ Ð ^ 2/dx ^ 2 - 0.25 * Ð ^ 3/dx ^ 3）== 0 Ÿ 它可以解决使用以下代码： Ž = linspace（0,1,512） x = linspace（-5,5,1024） psi0 =进出口（- x的。^ 2） Ð = D_lateral1D（十，2）-0.25 * D_lateral1D（十，3） 字段= LinearBPM（psi0，有D，Z） 凡D_lateral1D是一个函数，提供“取代”的微分算子。 这个函数是在一个非线性的BPM，我曾对（分步，谱方法等），将提交给我，当我完成他们的文件和组织功能更复杂的设置非常初期阶段。 (This is a simple FFT based beam propagation method for potential-free 1+1+1D Schrodinger equation. The software if flexible and allows to introduce high-order derivatives in the term (very handful if is needed to include dispersion effects). For example, if one desires to solve an equation in the form: (d/dz+ d^2/dx^2- 0.25*d^3/dx^3)Y == 0 It can be solved using the following code: z=linspace(0,1,512) x=linspace(-5,5,1024) psi0=exp(-x.^2) D=D_lateral1D(x,2)-0.25*D_lateral1D(x,3) field=LinearBPM(psi0,D,z) Where D_lateral1D is a provided function that "replaces" the derivative operator. This function is a very early stage in a more complex set of non-linear BPM functions that I have made (split-step, spectral methods, etc.) and I will submit them when I finish their documentation and organization. Sorry for my English, I m eager for your comments. )