qam16

用matlab编写的单相半控整流器，适合初学者(Prepared using matlab single-phase half-controlled rectifier, for beginners)

blind 多径信道中盲信道均衡的恒模算法(Blind multipath channel blind channel equalization of constant modulus algorithm)

用灰色系统理论设计自适应的PID控制!能够实现PID在线调整,能够适应环境的变化(gray design adaptive systems theory of PID control! PID can be achieved online adjustments, be able to adapt to environmental change)

独立成分分析JADE算法，针对复数数据 独立成分分析JADE算法，针对复数数据(The JADE algorithm of Independent Component Analysis Complex data )

一个基于ICA的图像分离算法的MATLAB程序，包含了文章，几个源程序，和说明文档。(An ICA-based image separation algorithm MATLAB program, contains articles, a few source code, and documentation.)

针对频率周期振荡的振动系统讨论自适应控制问题,在频率跟踪的基础上对频率变化的振动响应进行控 制,给出相应的估计、滤波与控制方法。首先在子空间辨识原理的基础上,通过测量信号自相关序列的递推运算获得信号 频率 然后根据估计频率实时调整带通滤波器的中心频率,使其跟踪信号频率,实现信号分量的跟踪滤波 最后在LMS方 法的基础上构造对信号分量进行控制的自适应控制器。(The adaptive vibration control of systems excited by forces of periodically varying frequencieswas dis- cussed. The presented adaptive controlwas realized on the basis of tracking of time-varying frequencies and amethod for online frequency estimation, filtering and controlwas proposed. Based on the principle of subspace identification, the time-varying frequencieswere estimated from the recursively computed autocorrelation ofmeasured signals. )

数值分析例题，包括欧拉法、龙格-库塔法、牛顿拉夫逊算法、牛顿-斯柯特和高斯消元法(Gaussian Elimination Row Operations Newton Raphson Newton-Cotes integration Euler s method Runga-Kutta gaussjordan)

matlab读取excel的程序 matlab读取excel的程序(matlab)

仿真MATLAB，史密斯，模糊，神经网络都有 SIMULINK搭建(Simulation MATLAB, Smith, fuzzy, neural network structures have SIMULINK)

Bloch simulator. [mx,my,mz] = bloch(b1,gr,tp,t1,t2,df,dp,mode,mx,my,mz) Bloch simulation of rotations due to B1, gradient and off-resonance, including relaxation effects. At each time point, the rotation matrix and decay matrix are calculated. Simulation can simulate the steady-state if the sequence is applied repeatedly, or the magnetization starting at m0. INPUT: b1 = (Mx1) RF pulse in G. Can be complex. gr = (Mx1,2,or 3) 1,2 or 3-dimensional gradient in G/cm. tp = (Mx1) time duration of each b1 and gr point, in seconds, or 1x1 time step if constant for all points