Provided by: gromacs-data_2023.3-1ubuntu3_all bug

NAME
       gmx-anaeig - Analyze eigenvectors/normal modes


SYNOPSIS
          gmx anaeig [-v [<.trr/.cpt/...>]] [-v2 [<.trr/.cpt/...>]]
                     [-f [<.xtc/.trr/...>]] [-s [<.tpr/.gro/...>]]
                     [-n [<.ndx>]] [-eig [<.xvg>]] [-eig2 [<.xvg>]]
                     [-comp [<.xvg>]] [-rmsf [<.xvg>]] [-proj [<.xvg>]]
                     [-2d [<.xvg>]] [-3d [<.gro/.g96/...>]]
                     [-filt [<.xtc/.trr/...>]] [-extr [<.xtc/.trr/...>]]
                     [-over [<.xvg>]] [-inpr [<.xpm>]] [-b <time>] [-e <time>]
                     [-dt <time>] [-tu <enum>] [-[no]w] [-xvg <enum>]
                     [-first <int>] [-last <int>] [-skip <int>] [-max <real>]
                     [-nframes <int>] [-[no]split] [-[no]entropy]
                     [-temp <real>] [-nevskip <int>]


DESCRIPTION
       gmx  anaeig  analyzes  eigenvectors.  The  eigenvectors can be of a covariance matrix (gmx covar) or of a
       Normal Modes analysis (gmx nmeig).

       When a trajectory is projected on eigenvectors, all  structures  are  fitted  to  the  structure  in  the
       eigenvector file, if present, otherwise to the structure in the structure file. When no run input file is
       supplied,  periodicity will not be taken into account. Most analyses are performed on eigenvectors -first
       to -last, but when -first is set to -1 you will be prompted for a selection.

       -comp: plot the vector components per atom of eigenvectors -first to -last.

       -rmsf: plot the RMS fluctuation per atom of eigenvectors -first to -last (requires -eig).

       -proj: calculate projections of a trajectory on eigenvectors -first  to  -last.   The  projections  of  a
       trajectory  on  the  eigenvectors of its covariance matrix are called principal components (pc's).  It is
       often useful to check the cosine content of the pc's, since the pc's of random diffusion are cosines with
       the number of periods equal to half the pc index.  The cosine content of the pc's can be calculated  with
       the program gmx analyze.

       -2d: calculate a 2d projection of a trajectory on eigenvectors -first and -last.

       -3d: calculate a 3d projection of a trajectory on the first three selected eigenvectors.

       -filt: filter the trajectory to show only the motion along eigenvectors -first to -last.

       -extr:  calculate the two extreme projections along a trajectory on the average structure and interpolate
       -nframes frames between them, or set your own extremes with -max. The eigenvector -first will be  written
       unless  -first  and  -last  have  been  set explicitly, in which case all eigenvectors will be written to
       separate files. Chain identifiers will be added when writing a .pdb file with  two  or  three  structures
       (you can use rasmol -nmrpdb to view such a .pdb file).

   Overlap calculations between covariance analysis
       Note: the analysis should use the same fitting structure

       -over:  calculate  the subspace overlap of the eigenvectors in file -v2 with eigenvectors -first to -last
       in file -v.

       -inpr: calculate a matrix of inner-products between eigenvectors in files -v and -v2. All eigenvectors of
       both files will be used unless -first and -last have been set explicitly.

       When -v and -v2 are given, a single number for the overlap between the covariance matrices is  generated.
       Note  that  the  eigenvalues are by default read from the timestamp field in the eigenvector input files,
       but when -eig, or -eig2 are given, the corresponding eigenvalues are used instead. The formulas are:

                  difference = sqrt(tr((sqrt(M1) - sqrt(M2))^2))
          normalized overlap = 1 - difference/sqrt(tr(M1) + tr(M2))
               shape overlap = 1 - sqrt(tr((sqrt(M1/tr(M1)) - sqrt(M2/tr(M2)))^2))

       where M1 and M2 are the two covariance matrices and tr  is  the  trace  of  a  matrix.  The  numbers  are
       proportional  to  the  overlap of the square root of the fluctuations. The normalized overlap is the most
       useful number, it is 1 for identical matrices and 0 when the sampled subspaces are orthogonal.

       When the -entropy flag is given an entropy estimate will be computed based on the Quasiharmonic  approach
       and based on Schlitter's formula.


OPTIONS
       Options to specify input files:

       -v [<.trr/.cpt/...>] (eigenvec.trr)
              Full precision trajectory: trr cpt tng

       -v2 [<.trr/.cpt/...>] (eigenvec2.trr) (Optional)
              Full precision trajectory: trr cpt tng

       -f [<.xtc/.trr/...>] (traj.xtc) (Optional)
              Trajectory: xtc trr cpt gro g96 pdb tng

       -s [<.tpr/.gro/...>] (topol.tpr) (Optional)
              Structure+mass(db): tpr gro g96 pdb brk ent

       -n [<.ndx>] (index.ndx) (Optional)
              Index file

       -eig [<.xvg>] (eigenval.xvg) (Optional)
              xvgr/xmgr file

       -eig2 [<.xvg>] (eigenval2.xvg) (Optional)
              xvgr/xmgr file

       Options to specify output files:

       -comp [<.xvg>] (eigcomp.xvg) (Optional)
              xvgr/xmgr file

       -rmsf [<.xvg>] (eigrmsf.xvg) (Optional)
              xvgr/xmgr file

       -proj [<.xvg>] (proj.xvg) (Optional)
              xvgr/xmgr file

       -2d [<.xvg>] (2dproj.xvg) (Optional)
              xvgr/xmgr file

       -3d [<.gro/.g96/...>] (3dproj.pdb) (Optional)
              Structure file: gro g96 pdb brk ent esp

       -filt [<.xtc/.trr/...>] (filtered.xtc) (Optional)
              Trajectory: xtc trr cpt gro g96 pdb tng

       -extr [<.xtc/.trr/...>] (extreme.pdb) (Optional)
              Trajectory: xtc trr cpt gro g96 pdb tng

       -over [<.xvg>] (overlap.xvg) (Optional)
              xvgr/xmgr file

       -inpr [<.xpm>] (inprod.xpm) (Optional)
              X PixMap compatible matrix file

       Other options:

       -b <time> (0)
              Time of first frame to read from trajectory (default unit ps)

       -e <time> (0)
              Time of last frame to read from trajectory (default unit ps)

       -dt <time> (0)
              Only use frame when t MOD dt = first time (default unit ps)

       -tu <enum> (ps)
              Unit for time values: fs, ps, ns, us, ms, s

       -[no]w (no)
              View output .xvg, .xpm, .eps and .pdb files

       -xvg <enum> (xmgrace)
              xvg plot formatting: xmgrace, xmgr, none

       -first <int> (1)
              First eigenvector for analysis (-1 is select)

       -last <int> (-1)
              Last eigenvector for analysis (-1 is till the last)

       -skip <int> (1)
              Only analyse every nr-th frame

       -max <real> (0)
              Maximum for projection of the eigenvector on the average structure, max=0 gives the extremes

       -nframes <int> (2)
              Number of frames for the extremes output

       -[no]split (no)
              Split eigenvector projections where time is zero

       -[no]entropy (no)
              Compute entropy according to the Quasiharmonic formula or Schlitter's method.

       -temp <real> (298.15)
              Temperature for entropy calculations

       -nevskip <int> (6)
              Number  of eigenvalues to skip when computing the entropy due to the quasi harmonic approximation.
              When you do a rotational and/or translational fit prior to the covariance analysis, you get 3 or 6
              eigenvalues that are very close to zero, and which should not be taken into account when computing
              the entropy.


SEE ALSO
       gmx(1)

       More information about GROMACS is available at <http://www.gromacs.org/>.


COPYRIGHT
       2023, GROMACS development team

2023.3                                            Oct 19, 2023                                     GMX-ANAEIG(1)