source: orxonox.OLD/orxonox/trunk/src/lib/newmat/eigen.cpp @ 4568

/*******************************************************
 A simple program that demonstrates NewMat10 library.
 The program defines a random symmetric matrix
 and computes its eigendecomposition.
 For further details read the NewMat10 Reference Manual
********************************************************/


#define WANT_STREAM
#define WANT_MATH
#define WANT_FSTREAM



#include <stdlib.h>
#include <time.h>
#include <string.h>

// the following two are needed for printing
#include <iostream.h>
#include <iomanip.h>
/**************************************
 The NewMat10 include files         */
#include "include.h"
#include "newmat.h"
#include "newmatap.h"
#include "newmatio.h"
/***************************************/


#ifdef use_namespace
using namespace RBD_LIBRARIES;
#endif

int main(int argc, char **argv) {

 
  SymmetricMatrix C(3);

  C(1,1) = 1;
  C(1,2) = 4;
  C(1,3) = 4;
  C(2,1) = 4;  
  C(2,2) = 2;
  C(2,3) = 4;
  C(3,1) = 4;
  C(3,2) = 4;
  C(3,3) = 3;
  
  cout << "The symmetrix matrix C" << endl;
  cout << setw(5) << setprecision(0) << C << endl;

  Matrix                V(3,3); // for eigenvectors
  DiagonalMatrix        D(3);   // for eigenvalues
  
  // the decomposition
  Jacobi(C, D, V);


  // Print the result
  cout << "The eigenvalues matrix:" << endl;
  cout << setw(10) << setprecision(5) << D << endl;
  cout << "The eigenvectors matrix:" << endl;
  cout << setw(10) << setprecision(5) << V << endl;

  return 0;
  /*
  int M = 3, N = 5;
  Matrix X(M,N); // Define an M x N general matrix

  // Fill X by random numbers between 0 and 9
  // Note that indexing into matrices in NewMat is 1-based!
  srand(time(NULL));
  for (int i = 1; i <= M; ++i) {
    for (int j = 1; j <= N; ++j) {
      X(i,j) = rand() % 10;
    }
  }

  SymmetricMatrix C;
  C << X * X.t(); // fill in C by X * X^t. 
  // Works because we *know* that the result is symmetric

  cout << "The symmetrix matrix C" << endl;
  cout << setw(5) << setprecision(0) << C << endl;
        

  // compute eigendecomposition of C
  Matrix                        V(3,3); // for eigenvectors
  DiagonalMatrix        D(3);   // for eigenvalues

  // the decomposition
  Jacobi(C, D, V);
        
  // Print the result
  cout << "The eigenvalues matrix:" << endl;
  cout << setw(10) << setprecision(5) << D << endl;
  cout << "The eigenvectors matrix:" << endl;
  cout << setw(10) << setprecision(5) << V << endl;

  // Check that the first eigenvector indeed has the eigenvector property
  ColumnVector v1(3);
  v1(1) = V(1,1);
  v1(2) = V(2,1);
  v1(3) = V(3,1);

  ColumnVector Cv1 = C * v1;
  ColumnVector lambda1_v1 = D(1) * v1;

  cout << "The max-norm of the difference between C*v1 and lambda1*v1 is " <<
    NormInfinity(Cv1 - lambda1_v1) << endl << endl;

  // Build the inverse and check the result
  Matrix Ci = C.i();
  Matrix I  = Ci * C;

  cout << "The inverse of C is" << endl;
  cout << setw(10) << setprecision(5) << Ci << endl;
  cout << "And the inverse times C is identity" << endl;
  cout << setw(10) << setprecision(5) << I << endl;

  // Example for multiple solves (see NewMat documentation)
  ColumnVector r1(3), r2(3);
  for (int i = 1; i <= 3; ++i) {
    r1(i) = rand() % 10;
    r2(i) = rand() % 10;
  }
  LinearEquationSolver CLU = C; // decomposes C
  ColumnVector s1 = CLU.i() * r1;
  ColumnVector s2 = CLU.i() * r2;

  cout << "solution for right hand side r1" << endl;
  cout << setw(10) << setprecision(5) << s1 << endl;
  cout << "solution for right hand side r2" << endl;
  cout << setw(10) << setprecision(5) << s2 << endl;
  */

  return 0;
}