1.python代码
import numpy as np
import pandas as pd
df=pd.DataFrame()
df['fac_01']=(34, 45, 65)
df['fac_02']=(56, 25, 94)
print(df)
print('------------------矩阵的特征跟D、和特征向量U-----------------------')
D,U=np.linalg.eig(np.dot(df.T, df)) # 求矩阵的特征跟D、和特征向量U
print(D,U,sep='\n')
print('\n------------------对角矩阵-----------------------')
print(np.diag(D**(-0.5)))
print('\n------------------对称正交后的矩阵-----------------------')
S = np.dot(np.dot(U, np.diag(D**(-0.5))), U.T) # 求过渡矩阵S = U* DEx *U'
F_hat = np.dot(df, S) # 求对称正交后的矩阵
print(F_hat)
2.C++的Eigen库实现
#include "Eigen/Dense"
using namespace Eigen;
int main()
{
//初始化
MatrixXf A(3, 2);
A(0,0) = 34;A(0,1) = 56;
A(1,0) = 45;A(1,1) = 25;
A(2,0) = 65;A(2,1) = 94;
//生成正交矩阵
MatrixXf AEx = A.transpose() * A;
int nRowSize = AEx.rows();
int nColSize = AEx.cols();
//求特征根、特征向量
SelfAdjointEigenSolver<Matrix2f> eigensolver(AEx);
MatrixXf D = eigensolver.eigenvalues();
MatrixXf U = eigensolver.eigenvectors();
std::cout<<"特征根如下:" <<std::endl;
nRowSize = D.rows();
nColSize = D.cols();
for(size_t i=0; i<nRowSize; i++)
{
for(size_t j=0; j<nColSize; j++)
{
std::cout<<D(i,j)<<" ";
}
std::cout<<std::endl;
}
std::cout<<"特征向量如下:" <<std::endl;
nRowSize = U.rows();
nColSize = U.cols();
for(size_t i=0; i<nRowSize; i++)
{
for(size_t j=0; j<nColSize; j++)
{
std::cout<<U(i,j)<<" ";
}
std::cout<<std::endl;
}
//生成np.diag(D**(-0.5)))对角线矩阵
MatrixXf DEx(2,2);
for(size_t i=0; i<2; i++)
{
for(size_t j=0; j<2; j++)
{
if(i == j)
{
DEx(i,j) = pow(D(i,0),-0.5);
}
else
{
DEx(i,j) = 0;
}
}
}
nRowSize = DEx.rows();
nColSize = DEx.cols();
std::cout<<"对角线矩阵如下:" <<std::endl;
for(size_t i=0; i<nRowSize; i++)
{
for(size_t j=0; j<nColSize; j++)
{
std::cout<<DEx(i,j)<<" ";
}
std::cout<<std::endl;
}
//生成过度矩阵S
MatrixXf S = U * DEx * U.transpose();
//生成正交化矩阵
MatrixXf R = A * S;
nRowSize = R.rows();
nColSize = R.cols();
std::cout<<"正交化结果如下:" <<std::endl;
for(size_t i=0; i<nRowSize; i++)
{
for(size_t j=0; j<nColSize; j++)
{
std::cout<<R(i,j)<<" ";
}
std::cout<<std::endl;
}
return 0;
}
3.结果对比
