doc/v630/TMatrixDEigen_8cxx_source.html

// @(#)root/matrix:$Id$

// Authors: Fons Rademakers, Eddy Offermann  Dec 2003


/*************************************************************************

 * Copyright (C) 1995-2000, Rene Brun and Fons Rademakers.               *

 * All rights reserved.                                                  *

 *                                                                       *

 * For the licensing terms see $ROOTSYS/LICENSE.                         *

 * For the list of contributors see $ROOTSYS/README/CREDITS.             *

 *************************************************************************/


/** \class TMatrixDEigen

    \ingroup Matrix


 TMatrixDEigen


 Eigenvalues and eigenvectors of a real matrix.


 If A is not symmetric, then the eigenvalue matrix D is block

 diagonal with the real eigenvalues in 1-by-1 blocks and any complex

 eigenvalues, a + i*b, in 2-by-2 blocks, [a, b; -b, a].  That is, if

 the complex eigenvalues look like


~~~

     u + iv     .        .          .      .    .

       .      u - iv     .          .      .    .

       .        .      a + ib       .      .    .

       .        .        .        a - ib   .    .

       .        .        .          .      x    .

       .        .        .          .      .    y

~~~


 then D looks like


~~~

       u        v        .          .      .    .

      -v        u        .          .      .    .

       .        .        a          b      .    .

       .        .       -b          a      .    .

       .        .        .          .      x    .

       .        .        .          .      .    y

~~~


 This keeps V a real matrix in both symmetric and non-symmetric

 cases, and A*V = V*D.


*/


#include "TMatrixDEigen.h"

#include "TMath.h"


ClassImp(TMatrixDEigen);


////////////////////////////////////////////////////////////////////////////////

/// Constructor for eigen-problem of matrix A .


TMatrixDEigen::TMatrixDEigen(const TMatrixD &a)

{

   R__ASSERT(a.IsValid());


   const Int_t nRows  = a.GetNrows();

   const Int_t nCols  = a.GetNcols();

   const Int_t rowLwb = a.GetRowLwb();

   const Int_t colLwb = a.GetColLwb();


   if (nRows != nCols || rowLwb != colLwb)

   {

      Error("TMatrixDEigen(TMatrixD &)","matrix should be square");

      return;

   }


   const Int_t rowUpb = rowLwb+nRows-1;

   fEigenVectors.ResizeTo(rowLwb,rowUpb,rowLwb,rowUpb);

   fEigenValuesRe.ResizeTo(rowLwb,rowUpb);

   fEigenValuesIm.ResizeTo(rowLwb,rowUpb);


   TVectorD ortho;

   Double_t work[kWorkMax];

   if (nRows > kWorkMax) ortho.ResizeTo(nRows);

   else                  ortho.Use(nRows,work);


   TMatrixD mH = a;


   // Reduce to Hessenberg form.

   MakeHessenBerg(fEigenVectors,ortho,mH);


   // Reduce Hessenberg to real Schur form.

   MakeSchurr(fEigenVectors,fEigenValuesRe,fEigenValuesIm,mH);


   // Sort eigenvalues and corresponding vectors in descending order of Re^2+Im^2

   // of the complex eigenvalues .

   Sort(fEigenVectors,fEigenValuesRe,fEigenValuesIm);

}


////////////////////////////////////////////////////////////////////////////////

/// Copy constructor


TMatrixDEigen::TMatrixDEigen(const TMatrixDEigen &another)

{

   *this = another;

}


////////////////////////////////////////////////////////////////////////////////

/// Nonsymmetric reduction to Hessenberg form.

/// This is derived from the Algol procedures orthes and ortran, by Martin and Wilkinson,

/// Handbook for Auto. Comp., Vol.ii-Linear Algebra, and the corresponding

/// Fortran subroutines in EISPACK.


void TMatrixDEigen::MakeHessenBerg(TMatrixD &v,TVectorD &ortho,TMatrixD &H)

{

   Double_t *pV = v.GetMatrixArray();

   Double_t *pO = ortho.GetMatrixArray();

   Double_t *pH = H.GetMatrixArray();


   const UInt_t n = v.GetNrows();


   const UInt_t low  = 0;

   const UInt_t high = n-1;


   UInt_t i,j,m;

   for (m = low+1; m <= high-1; m++) {

      const UInt_t off_m = m*n;


      // Scale column.


      Double_t scale = 0.0;

      for (i = m; i <= high; i++) {

         const UInt_t off_i = i*n;

         scale = scale + TMath::Abs(pH[off_i+m-1]);

      }

      if (scale != 0.0) {


         // Compute Householder transformation.


         Double_t h = 0.0;

         for (i = high; i >= m; i--) {

            const UInt_t off_i = i*n;

            pO[i] = pH[off_i+m-1]/scale;

            h += pO[i]*pO[i];

         }

         Double_t g = TMath::Sqrt(h);

         if (pO[m] > 0)

            g = -g;

         h = h-pO[m]*g;

         pO[m] = pO[m]-g;


         // Apply Householder similarity transformation

         // H = (I-u*u'/h)*H*(I-u*u')/h)


         for (j = m; j < n; j++) {

            Double_t f = 0.0;

            for (i = high; i >= m; i--) {

               const UInt_t off_i = i*n;

               f += pO[i]*pH[off_i+j];

            }

            f = f/h;

            for (i = m; i <= high; i++) {

               const UInt_t off_i = i*n;

               pH[off_i+j] -= f*pO[i];

            }

         }


         for (i = 0; i <= high; i++) {

            const UInt_t off_i = i*n;

            Double_t f = 0.0;

            for (j = high; j >= m; j--)

               f += pO[j]*pH[off_i+j];

            f = f/h;

            for (j = m; j <= high; j++)

               pH[off_i+j] -= f*pO[j];

         }

         pO[m] = scale*pO[m];

         pH[off_m+m-1] = scale*g;

      }

   }


   // Accumulate transformations (Algol's ortran).


   for (i = 0; i < n; i++) {

      const UInt_t off_i = i*n;

      for (j = 0; j < n; j++)

         pV[off_i+j] = (i == j ? 1.0 : 0.0);

   }


   for (m = high-1; m >= low+1; m--) {

      const UInt_t off_m = m*n;

      if (pH[off_m+m-1] != 0.0) {

         for (i = m+1; i <= high; i++) {

            const UInt_t off_i = i*n;

            pO[i] = pH[off_i+m-1];

         }

         for (j = m; j <= high; j++) {

            Double_t g = 0.0;

            for (i = m; i <= high; i++) {

               const UInt_t off_i = i*n;

               g += pO[i]*pV[off_i+j];

            }

            // Double division avoids possible underflow

            g = (g/pO[m])/pH[off_m+m-1];

            for (i = m; i <= high; i++) {

               const UInt_t off_i = i*n;

               pV[off_i+j] += g*pO[i];

            }

         }

      }

   }

}


////////////////////////////////////////////////////////////////////////////////

/// Complex scalar division.


static Double_t gCdivr, gCdivi;

static void cdiv(Double_t xr,Double_t xi,Double_t yr,Double_t yi) {

   Double_t r,d;

   if (TMath::Abs(yr) > TMath::Abs(yi)) {

      r = yi/yr;

      d = yr+r*yi;

      gCdivr = (xr+r*xi)/d;

      gCdivi = (xi-r*xr)/d;

   } else {

      r = yr/yi;

      d = yi+r*yr;

      gCdivr = (r*xr+xi)/d;

      gCdivi = (r*xi-xr)/d;

   }

}


////////////////////////////////////////////////////////////////////////////////

/// Nonsymmetric reduction from Hessenberg to real Schur form.

/// This is derived from the Algol procedure hqr2, by Martin and Wilkinson,

/// Handbook for Auto. Comp., Vol.ii-Linear Algebra, and the corresponding

/// Fortran subroutine in EISPACK.


void TMatrixDEigen::MakeSchurr(TMatrixD &v,TVectorD &d,TVectorD &e,TMatrixD &H)

{

   // Initialize


   const Int_t nn = v.GetNrows();

         Int_t n = nn-1;

   const Int_t low = 0;

   const Int_t high = nn-1;

   const Double_t eps = TMath::Power(2.0,-52.0);

   Double_t exshift = 0.0;

   Double_t p=0,q=0,r=0,s=0,z=0,t,w,x,y;


   Double_t *pV = v.GetMatrixArray();

   Double_t *pD = d.GetMatrixArray();

   Double_t *pE = e.GetMatrixArray();

   Double_t *pH = H.GetMatrixArray();


   // Store roots isolated by balanc and compute matrix norm


   Double_t norm = 0.0;

   Int_t i,j,k;

   for (i = 0; i < nn; i++) {

      const Int_t off_i = i*nn;

      if ((i < low) || (i > high)) {

         pD[i] = pH[off_i+i];

         pE[i] = 0.0;

      }

      for (j = TMath::Max(i-1,0); j < nn; j++)

         norm += TMath::Abs(pH[off_i+j]);

   }


   // Outer loop over eigenvalue index


   Int_t iter = 0;

   while (n >= low) {

      const Int_t off_n  = n*nn;

      const Int_t off_n1 = (n-1)*nn;


      // Look for single small sub-diagonal element


      Int_t l = n;

      while (l > low) {

         const Int_t off_l1 = (l-1)*nn;

         const Int_t off_l  = l*nn;

         s = TMath::Abs(pH[off_l1+l-1])+TMath::Abs(pH[off_l+l]);

         if (s == 0.0)

            s = norm;

         if (TMath::Abs(pH[off_l+l-1]) < eps*s)

            break;

         l--;

      }


      // Check for convergence

      // One root found


      if (l == n) {

         pH[off_n+n] = pH[off_n+n]+exshift;

         pD[n] = pH[off_n+n];

         pE[n] = 0.0;

         n--;

         iter = 0;


         // Two roots found


      } else if (l == n-1) {

         w = pH[off_n+n-1]*pH[off_n1+n];

         p = (pH[off_n1+n-1]-pH[off_n+n])/2.0;

         q = p*p+w;

         z = TMath::Sqrt(TMath::Abs(q));

         pH[off_n+n] = pH[off_n+n]+exshift;

         pH[off_n1+n-1] = pH[off_n1+n-1]+exshift;

         x = pH[off_n+n];


         // Double_t pair


         if (q >= 0) {

            if (p >= 0)

               z = p+z;

            else

               z = p-z;

            pD[n-1] = x+z;

            pD[n] = pD[n-1];

            if (z != 0.0)

               pD[n] = x-w/z;

            pE[n-1] = 0.0;

            pE[n] = 0.0;

            x = pH[off_n+n-1];

            s = TMath::Abs(x)+TMath::Abs(z);

            p = x/s;

            q = z/s;

            r = TMath::Sqrt((p*p)+(q*q));

            p = p/r;

            q = q/r;


            // Row modification


            for (j = n-1; j < nn; j++) {

               z = pH[off_n1+j];

               pH[off_n1+j] = q*z+p*pH[off_n+j];

               pH[off_n+j]  = q*pH[off_n+j]-p*z;

            }


            // Column modification


            for (i = 0; i <= n; i++) {

               const Int_t off_i = i*nn;

               z = pH[off_i+n-1];

               pH[off_i+n-1] = q*z+p*pH[off_i+n];

               pH[off_i+n]  = q*pH[off_i+n]-p*z;

            }


            // Accumulate transformations


            for (i = low; i <= high; i++) {

               const Int_t off_i = i*nn;

               z = pV[off_i+n-1];

               pV[off_i+n-1] = q*z+p*pV[off_i+n];

               pV[off_i+n]   = q*pV[off_i+n]-p*z;

            }


            // Complex pair


         } else {

            pD[n-1] = x+p;

            pD[n] = x+p;

            pE[n-1] = z;

            pE[n] = -z;

         }

         n = n-2;

         iter = 0;


         // No convergence yet


      } else {


         // Form shift


         x = pH[off_n+n];

         y = 0.0;

         w = 0.0;

         if (l < n) {

            y = pH[off_n1+n-1];

            w = pH[off_n+n-1]*pH[off_n1+n];

         }


         // Wilkinson's original ad hoc shift


         if (iter == 10) {

            exshift += x;

            for (i = low; i <= n; i++) {

               const Int_t off_i = i*nn;

               pH[off_i+i] -= x;

            }

            s = TMath::Abs(pH[off_n+n-1])+TMath::Abs(pH[off_n1+n-2]);

            x = y = 0.75*s;

            w = -0.4375*s*s;

         }


         // MATLAB's new ad hoc shift


         if (iter == 30) {

            s = (y-x)/2.0;

            s = s*s+w;

            if (s > 0) {

               s = TMath::Sqrt(s);

               if (y<x)

                  s = -s;

               s = x-w/((y-x)/2.0+s);

               for (i = low; i <= n; i++) {

                  const Int_t off_i = i*nn;

                  pH[off_i+i] -= s;

               }

               exshift += s;

               x = y = w = 0.964;

            }

         }


         if (iter++ == 50) {  // (check iteration count here.)

            Error("MakeSchurr","too many iterations");

            break;

         }


         // Look for two consecutive small sub-diagonal elements


         Int_t m = n-2;

         while (m >= l) {

            const Int_t off_m   = m*nn;

            const Int_t off_m_1 = (m-1)*nn;

            const Int_t off_m1  = (m+1)*nn;

            const Int_t off_m2  = (m+2)*nn;

            z = pH[off_m+m];

            r = x-z;

            s = y-z;

            p = (r*s-w)/pH[off_m1+m]+pH[off_m+m+1];

            q = pH[off_m1+m+1]-z-r-s;

            r = pH[off_m2+m+1];

            s = TMath::Abs(p)+TMath::Abs(q)+TMath::Abs(r);

            p = p /s;

            q = q/s;

            r = r/s;

            if (m == l)

               break;

            if (TMath::Abs(pH[off_m+m-1])*(TMath::Abs(q)+TMath::Abs(r)) <

               eps*(TMath::Abs(p)*(TMath::Abs(pH[off_m_1+m-1])+TMath::Abs(z)+

               TMath::Abs(pH[off_m1+m+1]))))

               break;

            m--;

         }


         for (i = m+2; i <= n; i++) {

            const Int_t off_i = i*nn;

            pH[off_i+i-2] = 0.0;

            if (i > m+2)

               pH[off_i+i-3] = 0.0;

         }


         // Double QR step involving rows l:n and columns m:n


         for (k = m; k <= n-1; k++) {

            const Int_t off_k  = k*nn;

            const Int_t off_k1 = (k+1)*nn;

            const Int_t off_k2 = (k+2)*nn;

            const Int_t notlast = (k != n-1);

            if (k != m) {

               p = pH[off_k+k-1];

               q = pH[off_k1+k-1];

               r = (notlast ? pH[off_k2+k-1] : 0.0);

               x = TMath::Abs(p)+TMath::Abs(q)+TMath::Abs(r);

               if (x != 0.0) {

                  p = p/x;

                  q = q/x;

                  r = r/x;

               }

            }

            if (x == 0.0)

               break;

            s = TMath::Sqrt(p*p+q*q+r*r);

            if (p < 0) {

               s = -s;

            }

            if (s != 0) {

              if (k != m)

                 pH[off_k+k-1] = -s*x;

              else if (l != m)

                 pH[off_k+k-1] = -pH[off_k+k-1];

              p = p+s;

              x = p/s;

              y = q/s;

              z = r/s;

              q = q/p;

              r = r/p;


              // Row modification


              for (j = k; j < nn; j++) {

                 p = pH[off_k+j]+q*pH[off_k1+j];

                 if (notlast) {

                    p = p+r*pH[off_k2+j];

                    pH[off_k2+j] = pH[off_k2+j]-p*z;

                 }

                 pH[off_k+j]  = pH[off_k+j]-p*x;

                 pH[off_k1+j] = pH[off_k1+j]-p*y;

              }


              // Column modification


              for (i = 0; i <= TMath::Min(n,k+3); i++) {

                 const Int_t off_i = i*nn;

                 p = x*pH[off_i+k]+y*pH[off_i+k+1];

                 if (notlast) {

                    p = p+z*pH[off_i+k+2];

                    pH[off_i+k+2] = pH[off_i+k+2]-p*r;

                 }

                 pH[off_i+k]   = pH[off_i+k]-p;

                 pH[off_i+k+1] = pH[off_i+k+1]-p*q;

              }


              // Accumulate transformations


              for (i = low; i <= high; i++) {

                 const Int_t off_i = i*nn;

                 p = x*pV[off_i+k]+y*pV[off_i+k+1];

                 if (notlast) {

                    p = p+z*pV[off_i+k+2];

                    pV[off_i+k+2] = pV[off_i+k+2]-p*r;

                 }

                 pV[off_i+k]   = pV[off_i+k]-p;

                 pV[off_i+k+1] = pV[off_i+k+1]-p*q;

              }

            }  // (s != 0)

         }  // k loop

      }  // check convergence

   }  // while (n >= low)


   // Backsubstitute to find vectors of upper triangular form


   if (norm == 0.0)

      return;


   for (n = nn-1; n >= 0; n--) {

      p = pD[n];

      q = pE[n];


      // Double_t vector


      const Int_t off_n = n*nn;

      if (q == 0) {

         Int_t l = n;

         pH[off_n+n] = 1.0;

         for (i = n-1; i >= 0; i--) {

            const Int_t off_i  = i*nn;

            const Int_t off_i1 = (i+1)*nn;

            w = pH[off_i+i]-p;

            r = 0.0;

            for (j = l; j <= n; j++) {

               const Int_t off_j = j*nn;

               r = r+pH[off_i+j]*pH[off_j+n];

            }

            if (pE[i] < 0.0) {

               z = w;

               s = r;

            } else {

               l = i;

               if (pE[i] == 0.0) {

                  if (w != 0.0)

                     pH[off_i+n] = -r/w;

                  else

                     pH[off_i+n] = -r/(eps*norm);


                  // Solve real equations


               } else {

                  x = pH[off_i+i+1];

                  y = pH[off_i1+i];

                  q = (pD[i]-p)*(pD[i]-p)+pE[i]*pE[i];

                  t = (x*s-z*r)/q;

                  pH[off_i+n] = t;

                  if (TMath::Abs(x) > TMath::Abs(z))

                     pH[i+1+n] = (-r-w*t)/x;

                  else

                     pH[i+1+n] = (-s-y*t)/z;

               }


               // Overflow control


               t = TMath::Abs(pH[off_i+n]);

               if ((eps*t)*t > 1) {

                  for (j = i; j <= n; j++) {

                     const Int_t off_j = j*nn;

                     pH[off_j+n] = pH[off_j+n]/t;

                  }

               }

            }

         }


         // Complex vector


      } else if (q < 0) {

         Int_t l = n-1;

         const Int_t off_n1 = (n-1)*nn;


         // Last vector component imaginary so matrix is triangular


         if (TMath::Abs(pH[off_n+n-1]) > TMath::Abs(pH[off_n1+n])) {

            pH[off_n1+n-1] = q/pH[off_n+n-1];

            pH[off_n1+n]   = -(pH[off_n+n]-p)/pH[off_n+n-1];

         } else {

            cdiv(0.0,-pH[off_n1+n],pH[off_n1+n-1]-p,q);

            pH[off_n1+n-1] = gCdivr;

            pH[off_n1+n]   = gCdivi;

         }

         pH[off_n+n-1] = 0.0;

         pH[off_n+n]   = 1.0;

         for (i = n-2; i >= 0; i--) {

            const Int_t off_i  = i*nn;

            const Int_t off_i1 = (i+1)*nn;

            Double_t ra = 0.0;

            Double_t sa = 0.0;

            for (j = l; j <= n; j++) {

               const Int_t off_j = j*nn;

               ra += pH[off_i+j]*pH[off_j+n-1];

               sa += pH[off_i+j]*pH[off_j+n];

            }

            w = pH[off_i+i]-p;


            if (pE[i] < 0.0) {

               z = w;

               r = ra;

               s = sa;

            } else {

               l = i;

               if (pE[i] == 0) {

                  cdiv(-ra,-sa,w,q);

                  pH[off_i+n-1] = gCdivr;

                  pH[off_i+n]   = gCdivi;

               } else {


                  // Solve complex equations


                  x = pH[off_i+i+1];

                  y = pH[off_i1+i];

                  Double_t vr = (pD[i]-p)*(pD[i]-p)+pE[i]*pE[i]-q*q;

                  Double_t vi = (pD[i]-p)*2.0*q;

                  if ((vr == 0.0) && (vi == 0.0)) {

                     vr = eps*norm*(TMath::Abs(w)+TMath::Abs(q)+

                          TMath::Abs(x)+TMath::Abs(y)+TMath::Abs(z));

                  }

                  cdiv(x*r-z*ra+q*sa,x*s-z*sa-q*ra,vr,vi);

                  pH[off_i+n-1] = gCdivr;

                  pH[off_i+n]   = gCdivi;

                  if (TMath::Abs(x) > (TMath::Abs(z)+TMath::Abs(q))) {

                     pH[off_i1+n-1] = (-ra-w*pH[off_i+n-1]+q*pH[off_i+n])/x;

                     pH[off_i1+n]   = (-sa-w*pH[off_i+n]-q*pH[off_i+n-1])/x;

                  } else {

                     cdiv(-r-y*pH[off_i+n-1],-s-y*pH[off_i+n],z,q);

                     pH[off_i1+n-1] = gCdivr;

                     pH[off_i1+n]   = gCdivi;

                  }

               }


               // Overflow control


               t = TMath::Max(TMath::Abs(pH[off_i+n-1]),TMath::Abs(pH[off_i+n]));

               if ((eps*t)*t > 1) {

                  for (j = i; j <= n; j++) {

                     const Int_t off_j = j*nn;

                     pH[off_j+n-1] = pH[off_j+n-1]/t;

                     pH[off_j+n]   = pH[off_j+n]/t;

                  }

               }

            }

         }

      }

   }


   // Vectors of isolated roots


   for (i = 0; i < nn; i++) {

      if (i < low || i > high) {

         const Int_t off_i = i*nn;

         for (j = i; j < nn; j++)

            pV[off_i+j] = pH[off_i+j];

      }

   }


   // Back transformation to get eigenvectors of original matrix


   for (j = nn-1; j >= low; j--) {

      for (i = low; i <= high; i++) {

         const Int_t off_i = i*nn;

         z = 0.0;

         for (k = low; k <= TMath::Min(j,high); k++) {

            const Int_t off_k = k*nn;

            z = z+pV[off_i+k]*pH[off_k+j];

         }

         pV[off_i+j] = z;

      }

   }


}


////////////////////////////////////////////////////////////////////////////////

/// Sort eigenvalues and corresponding vectors in descending order of Re^2+Im^2

/// of the complex eigenvalues .


void TMatrixDEigen::Sort(TMatrixD &v,TVectorD &d,TVectorD &e)

{

   // Sort eigenvalues and corresponding vectors.

   Double_t *pV = v.GetMatrixArray();

   Double_t *pD = d.GetMatrixArray();

   Double_t *pE = e.GetMatrixArray();


   const Int_t n = v.GetNrows();


   for (Int_t i = 0; i < n-1; i++) {

      Int_t k = i;

      Double_t norm = pD[i]*pD[i]+pE[i]*pE[i];

      Int_t j;

      for (j = i+1; j < n; j++) {

         const Double_t norm_new = pD[j]*pD[j]+pE[j]*pE[j];

         if (norm_new > norm) {

            k = j;

            norm = norm_new;

         }

      }

      if (k != i) {

         Double_t tmp;

         tmp   = pD[k];

         pD[k] = pD[i];

         pD[i] = tmp;

         tmp   = pE[k];

         pE[k] = pE[i];

         pE[i] = tmp;

         for (j = 0; j < n; j++) {

            const Int_t off_j = j*n;

            tmp = pV[off_j+i];

            pV[off_j+i] = pV[off_j+k];

            pV[off_j+k] = tmp;

         }

      }

   }

}


////////////////////////////////////////////////////////////////////////////////

/// Assignment operator


TMatrixDEigen &TMatrixDEigen::operator=(const TMatrixDEigen &source)

{

   if (this != &source) {

      fEigenVectors.ResizeTo(source.fEigenVectors);

      fEigenValuesRe.ResizeTo(source.fEigenValuesRe);

      fEigenValuesIm.ResizeTo(source.fEigenValuesIm);

      fEigenVectors = source.fEigenVectors;

      fEigenValuesRe = source.fEigenValuesRe;

      fEigenValuesIm = source.fEigenValuesIm;

   }

   return *this;

}


////////////////////////////////////////////////////////////////////////////////

/// Computes the block diagonal eigenvalue matrix.

/// If the original matrix A is not symmetric, then the eigenvalue

/// matrix D is block diagonal with the real eigenvalues in 1-by-1

/// blocks and any complex eigenvalues,

///    a + i*b, in 2-by-2 blocks, [a, b; -b, a].

///  That is, if the complex eigenvalues look like

///

/// ~~~

///     u + iv     .        .          .      .    .

///       .      u - iv     .          .      .    .

///       .        .      a + ib       .      .    .

///       .        .        .        a - ib   .    .

///       .        .        .          .      x    .

///       .        .        .          .      .    y

/// ~~~

///

/// then D looks like

///

/// ~~~

///     u        v        .          .      .    .

///    -v        u        .          .      .    .

///     .        .        a          b      .    .

///     .        .       -b          a      .    .

///     .        .        .          .      x    .

///     .        .        .          .      .    y

/// ~~~

///

/// This keeps V a real matrix in both symmetric and non-symmetric

/// cases, and A*V = V*D.

///

/// Indexing:

///  If matrix A has the index/shape (rowLwb,rowUpb,rowLwb,rowUpb)

///  each eigen-vector must have the shape (rowLwb,rowUpb) .

///  For convenience, the column index of the eigen-vector matrix

///  also runs from rowLwb to rowUpb so that the returned matrix

///  has also index/shape (rowLwb,rowUpb,rowLwb,rowUpb) .

///


const TMatrixD TMatrixDEigen::GetEigenValues() const

{

   const Int_t nrows  = fEigenVectors.GetNrows();

   const Int_t rowLwb = fEigenVectors.GetRowLwb();

   const Int_t rowUpb = rowLwb+nrows-1;


   TMatrixD mD(rowLwb,rowUpb,rowLwb,rowUpb);


   Double_t *pD = mD.GetMatrixArray();

   const Double_t * const pd = fEigenValuesRe.GetMatrixArray();

   const Double_t * const pe = fEigenValuesIm.GetMatrixArray();


   for (Int_t i = 0; i < nrows; i++) {

      const Int_t off_i = i*nrows;

      for (Int_t j = 0; j < nrows; j++)

         pD[off_i+j] = 0.0;

      pD[off_i+i] = pd[i];

      if (pe[i] > 0) {

         pD[off_i+i+1] = pe[i];

      } else if (pe[i] < 0) {

         pD[off_i+i-1] = pe[i];

      }

   }


   return mD;

}

d
#define d(i)
Definition RSha256.hxx:102

f
#define f(i)
Definition RSha256.hxx:104

g
#define g(i)
Definition RSha256.hxx:105

a
#define a(i)
Definition RSha256.hxx:99

h
#define h(i)
Definition RSha256.hxx:106

e
#define e(i)
Definition RSha256.hxx:103

Double_t
double Double_t
Definition RtypesCore.h:59

ClassImp
#define ClassImp(name)
Definition Rtypes.h:377

R__ASSERT
#define R__ASSERT(e)
Definition TError.h:118

Error
void Error(const char *location, const char *msgfmt,...)
Use this function in case an error occurred.
Definition TError.cxx:185

w
winID w
Definition TGWin32VirtualGLProxy.cxx:39

p
winID h TVirtualViewer3D TVirtualGLPainter p
Definition TGWin32VirtualGLProxy.cxx:51

r
Option_t Option_t TPoint TPoint const char GetTextMagnitude GetFillStyle GetLineColor GetLineWidth GetMarkerStyle GetTextAlign GetTextColor GetTextSize void char Point_t Rectangle_t WindowAttributes_t Float_t r
Definition TGWin32VirtualXProxy.cxx:168

q
float * q
Definition THbookFile.cxx:89

TMath.h

cdiv
static void cdiv(Double_t xr, Double_t xi, Double_t yr, Double_t yi)
Definition TMatrixDEigen.cxx:213

gCdivi
static Double_t gCdivi
Definition TMatrixDEigen.cxx:212

gCdivr
static Double_t gCdivr
Complex scalar division.
Definition TMatrixDEigen.cxx:212

TMatrixDEigen.h

TMatrixDEigen
TMatrixDEigen.
Definition TMatrixDEigen.h:27

TMatrixDEigen::fEigenValuesIm
TVectorD fEigenValuesIm
Definition TMatrixDEigen.h:36

TMatrixDEigen::MakeHessenBerg
static void MakeHessenBerg(TMatrixD &v, TVectorD &ortho, TMatrixD &H)
Nonsymmetric reduction to Hessenberg form.
Definition TMatrixDEigen.cxx:109

TMatrixDEigen::fEigenValuesRe
TVectorD fEigenValuesRe
Definition TMatrixDEigen.h:35

TMatrixDEigen::TMatrixDEigen
TMatrixDEigen()
Definition TMatrixDEigen.h:42

TMatrixDEigen::fEigenVectors
TMatrixD fEigenVectors
Definition TMatrixDEigen.h:34

TMatrixDEigen::GetEigenValues
const TMatrixD GetEigenValues() const
Computes the block diagonal eigenvalue matrix.
Definition TMatrixDEigen.cxx:792

TMatrixDEigen::operator=
TMatrixDEigen & operator=(const TMatrixDEigen &source)
Assignment operator.
Definition TMatrixDEigen.cxx:740

TMatrixDEigen::kWorkMax
@ kWorkMax
Definition TMatrixDEigen.h:40

TMatrixDEigen::Sort
static void Sort(TMatrixD &v, TVectorD &d, TVectorD &e)
Sort eigenvalues and corresponding vectors in descending order of Re^2+Im^2 of the complex eigenvalue...
Definition TMatrixDEigen.cxx:699

TMatrixDEigen::MakeSchurr
static void MakeSchurr(TMatrixD &v, TVectorD &d, TVectorD &e, TMatrixD &H)
Nonsymmetric reduction from Hessenberg to real Schur form.
Definition TMatrixDEigen.cxx:234

TMatrixTBase::GetNrows
Int_t GetNrows() const
Definition TMatrixTBase.h:123

TMatrixTBase::GetRowLwb
Int_t GetRowLwb() const
Definition TMatrixTBase.h:121

TMatrixT< Double_t >

TMatrixT::GetMatrixArray
const Element * GetMatrixArray() const override
Definition TMatrixT.h:227

TMatrixT::ResizeTo
TMatrixTBase< Element > & ResizeTo(Int_t nrows, Int_t ncols, Int_t=-1) override
Set size of the matrix to nrows x ncols New dynamic elements are created, the overlapping part of the...
Definition TMatrixT.cxx:1211

TVectorT< Double_t >

TVectorT::ResizeTo
TVectorT< Element > & ResizeTo(Int_t lwb, Int_t upb)
Resize the vector to [lwb:upb] .
Definition TVectorT.cxx:294

TVectorT::Use
TVectorT< Element > & Use(Int_t lwb, Int_t upb, Element *data)
Use the array data to fill the vector lwb..upb].
Definition TVectorT.cxx:349

TVectorT::GetMatrixArray
Element * GetMatrixArray()
Definition TVectorT.h:78

double

int

unsigned int

y
Double_t y[n]
Definition legend1.C:17

x
Double_t x[n]
Definition legend1.C:17

n
const Int_t n
Definition legend1.C:16

H
#define H(x, y, z)

TMath::Max
Short_t Max(Short_t a, Short_t b)
Returns the largest of a and b.
Definition TMathBase.h:250

TMath::Sqrt
Double_t Sqrt(Double_t x)
Returns the square root of x.
Definition TMath.h:662

TMath::Power
LongDouble_t Power(LongDouble_t x, LongDouble_t y)
Returns x raised to the power y.
Definition TMath.h:721

TMath::Min
Short_t Min(Short_t a, Short_t b)
Returns the smallest of a and b.
Definition TMathBase.h:198

TMath::Abs
Short_t Abs(Short_t d)
Returns the absolute value of parameter Short_t d.
Definition TMathBase.h:123

v
@ v
Definition rootcling_impl.cxx:3687

m
TMarker m
Definition textangle.C:8

l
TLine l
Definition textangle.C:4