stable(1) [debian man page]

stable(1)																 stable(1)

NAME

       stable - MO Hessian stability analysis program

DESCRIPTION

       The  program  stable  performs a stability analysis on the molecular orbitals by diagonalizing the molecular orbital Hessian.  The analysis
       includes orbital rotations which may break spin or spatial symmetry.  If an instability is detected (i.e., there are  negative  eigenvalues
       of  the	MO Hessian), the previous Hartree-Fock self consistent field (SCF) computation has landed on a local minimum, not the global mini-
       mum, in orbital rotation space.	For spatial- or symmetry-breaking rotations, this merely means that there is another orbital occupation or
       a  UHF  wavefunction  with a lower energy.  For instabilties which preserve the reference type (RHF or UHF) and are totally symmetric, this
       suggests that the SCF computation has simply found the wrong solution and should be re-run using a new initial guess.

       Instabilities corresponding to spatial symmetry breaking rotatios can be resolved by re-running the calculation in  a  lower  computational
       point  group.  (It may also be necessary to employ some trick to break the symmetry of the initial guess wavefunction).	Instabilities cor-
       responding to spin symmetry breaking rotations (RHF->UHF) can be resolved by re-running the SCF using a UHF reference.

       For UHF wavefunctions with totally-symmetric instabilities, it is possible to follow the instability automatically toward the global  mini-
       mum by setting FOLLOW=TRUE.

INPUT FORMAT

       Input for this program is read from the file The following keywords are valid:

       CACHELEV = integer
	      This  is	the  cache  level  used for the DPD files.  It functions the same way as in the coupled-cluster codes.	Currently, this is
	      hardwired to 0.

       FOLLOW = boolean
	      If TRUE, then the eigenvector corresponding to the most negative eigenvalue of the MO Hessian will be followed  to  try  to  find  a
	      lower  energy  Hartree-Fock  solution.   The  orbitals  will  be rotated, and the cscf module should be re-run using these new guess
	      orbitals.

       NUM_EVECS_PRINT = integer
	      Gives the number of MO Hessian eigenvectors to print.

       PRINT = integer
	      The print level determines how much information is printed by the program.  Values typically range from 1 (minimal  printing)  to  5
	      (very verbose printing for debugging only).  The default is 1.

       REFERENCE = string
	      This is the reference type, RHF, ROHF, or UHF.  The default is RHF.

       SCALE = real
	      This  is	the  scale factor used for taking steps in eigenvector following.  Normal values would be between 0 and 1.  The default is
	      0.5.

								    23 Aug, 2003							 stable(1)

cscf(1) 																   cscf(1)

NAME

       cscf - solves the Hartree-Fock equations

DESCRIPTION

       The program cscf carries out the iterative procedure to solve the Hartree-Fock equations.

       This  program  is restricted to D2h symmetry and its subgroups and the orbital occupations are required to be integers.	Thus, certain pure
       angular momentum states derived from partial occupation of degenerate orbitals cannot be obtained with the present codes.  For example, the
       2PIu  (doublet  PI  u)  state  of linear O-N-O derived from the lowest energy linear (pi u)1 configuration may only be computed as the 2B2u
       (doublet B2u) or 2B3u (doublet B 3u) component of the 2PIu (doublet PI u) state, and the resulting spatial wavefunction will  not  have	PI
       symmetry.   In  a certain sense, however, this is desirable, as the energy will be a continuous function of the bending angle.  Calculating
       the energy of bent configurations as 2B2u (doublet B 2u) or 2B3u (doublet B 3u) and doing a pure 2PIu (doublet PI u) state at linear geome-
       tries results in a pronounced discontinuity.

       For  the  most  part,  triplet  states resulting from double occupation of a doubly degenerate orbital, such as the 3A2 (triplet A 2) state
       resulting from the (e')2 or (e")2 configurations in D3h symmetry, or the 3SIGMAg (triplet SIGMA g) state of a (pi g)2 or (pi u)2 configura-
       tion  in Dinfh (D infinity h) symmetry, will have the proper spatial symetry.  The singlet states resulting from these same electronic con-
       figurations are inherently multiconfiguration and, as such, are not well represented by single configuration wavefunctions.

REFERENCES

       PK-file method:

       1.     R. C. Raffenetti, Chem. Phys. Lett. 20 (1973) 335.

       Molecular symmetry and closed shell HF calculations:

       1.     M.Dupuis, and H.F.King, Int. J. Quant. Chem.  11 (1977) 613.

       DIIS for closed shell:

       1.     P. Pulay, Chem. Phys. Lett. 73 (1980) 393.

       2.     P. Pulay, J. Comp. Chem. 3 (1982) 556.

       Coupling coefficients (alpha and beta) for open shell:

       1.     C. C. J. Roothaan, Rev. Mod. Phys. 32 (1960) 179.

       Damping:

       1.     D. R. Hartree, "The Calculation of Atomic Structures" (Wiley: New York) 1957.

       2.     M. C. Zerner and M. Hehenberger, Chem. Phys. Lett. 62 (1979) 550.

       Level shifting:

       1.     V. R. Saunders and I. H. Hillier, Int. J. Quant. Chem. 7 (1973) 699.

CONVERGING CSCF

       For difficult open shell cases, it is recommended that an appropriate closed shell calculation be run first (add or remove an  extra  elec-
       tron)  and that this SCF vector then be used as a guess for the desired open shell wavefunction.  For TCSCF cases, it is always wise to run
       a closed shell (or perhaps the appropriate triplet) SCF first and then use this as a guess for the TCSCF.

       For open shell systems, a level shift value of 0.5 to 3.0 is recommended.  Start with a high value (2.0 - 3.0) for the first  SCF  calcula-
       tion and then reduce it (to 0.5 - 1.0) for subsequent runs which use a converged SCF vector as the starting point.

       It  is  extremely important to note that this version of the code no longer supports OPENTYPE.  One must use the new keywords REFERENCE and
       MULTP to specify the type of SCF needed.

INPUT FORMAT

       The cscf program searches through the default keyword path (first SCF and then DEFAULT) for the following keywords:

       LABEL = string
	      This is a character string to be included in the output.	This string is not used by the program.  There is no default.

       WFN = string
	      This is the type of wavefunction which is ultimately desired.  The default is SCF.

       OPENTYPE is no longer supported

       REFERENCE = string
	      This specifies the type of SCF calculation one wants to do.  It can be one of  RHF  (for	a  closed  shell  singlet),  ROHF  (for  a
	      restricted  open	shell calculation), UHF (for an unrestricted open shell calculation), TWOCON (for a two configuration singlet), or
	      SPECIAL.	If SPECIAL is given, then alpha and beta coupling coefficients must be given  with  the  ALPHA	and  BETA  keywords.   The
	      default is RHF.

       MULTP= integer
	      Specifies the multiplicity of the molecule.  Default is singlet.

       CHARGE= integer
	      Specifies the charge of the molecule. Defauly is 0.

       DOCC = integer_vector
	      This  gives  the number of doubly occupied orbitals in each irreducible representation.  There is no default.  If this is not given,
	      CSCF will attempt to guess at the occupations using the core hamiltonian.

       SOCC = integer_vector
	      This gives the number of singly occupied orbitals in each irreducible representation. There is no default.

       DERTYPE = string
	      This specifies the order of derivative that is to eventually be done.  It is used by the scf program to determine if  certain  files
	      are to be written and it is also used to determine the default convergence of the wavefunction.  The default is FIRST.

       MAXITER = integer
	      This gives the maximum number of iterations.  The default is 40.

       CONVERGENCE = integer
	      This specifies how tightly the wavefunction will be converged.  Convergence is determined by comparing the RMS change in the density
	      matrix ("delta P") to the given value.  The convergence criterion is 10**(-integer).  The default is 7 if both DERTYPE  =  NONE  and
	      WFN = SCF are given and 10 otherwise.

       LEVELSHIFT = real
	      This specifies the level shift. The default is 1.

       DIRECT =  boolean
	      Specifies whether to do the SCF calculation with an integral direct technique.  The default is false.

       PRINT_MOS =  boolean
	      Specifies whether to print the molecular orbitals or not.  The default is false.

       There  are also a large number of less commonly used input parameters.  If you do not understand what the following options mean, then make
       sure that they do not appear in your input.  The defaults will work in the overwhelming majority of cases.  These are  specified  with  the
       following keywords:

       DELETE_INTS = boolean
	      Integrals  files	will  be  erased if WFN = SCF and DERTYPE = FIRST or DERTYPE = NONE.  If you wish to keep integrals files then set
	      DELETE_INTS = false.  The default is true.

       REORDER = string
	      The parameter controls reordering of molecular orbitals.	If set to BEFORE then the guess orbitals  from	checkpoint  file  will	be
	      reordered.  If  set  to  AFTER,  converged  orbitals  will be reordered before being written to the checkpoint file.  In either case
	      MOORDER parameter must be given to specify the reordering map. The default is not to reorder orbitals.

       MOORDER = integer_vector
	      This specifies a molecular orbital reordering vector.  It will only be used if REORDER is set.  This vector maps	every  orbital	to
	      its  new	index, e.g. MOORDER = (0 2 1) specifies that after reordering orbitals 1 and 2 will be swapped. The rank of this vector is
	      the same as the number of MOs. The indices are in Pitzer order (ordered by symmetry, then by energy  within  each  symmetry  block),
	      base-0.  CSCF will likely fail if the given MOORDER mixes orbitals from different irreps. There is no default.

       ALPHA = real_vector
	      If  OPENTYPE  =  SPECIAL,  then  this  parameter	gives  the  alpha coupling coefficients.  The number of elements in this vector is
	      MM(MM+1)/2, where MM is the number of irreducible representations containing  singly  occupied  molecular  orbitals.   There  is	no
	      default.

       BETA = real_vector
	      If  OPENTYPE  =  SPECIAL,  then  this  parameter	gives  the  beta  coupling coefficients.  The number of elements in this vector is
	      MM(MM+1)/2, where MM is the number of irreducible representations containing  singly  occupied  molecular  orbitals.   There  is	no
	      default.

       GUESS = string
	      This  option  determines	the  type of initial guess at the eigenvector CSCF will use. The only valid option at the moment are : (1)
	      GUESS = CORE, which causes it to use core Hamiltonian eigenvector to start the calculation; (2) GUESS = AUTO  which  results  in	an
	      attempt  to  use the MO vector in the checkpoint file, or resorts to core guess if there is no eigenvector in that file. The default
	      if AUTO.

       IPRINT = integer
	      This is a print option.  The default is 0.

       MO_OUT = boolean
	      Prints out the orbitals with symmetry and occupations at the end of the calculation.  Default is true.

       ROTATE = boolean
	      The molecular orbitals will not be rotated if this is false.  The rotation only affects the virtual orbitals for open shell systems.
	      This  parameter  must be true for correlated gradients and it must be false for second and higher derivatives.  The default is false
	      if WFN = SCF and true otherwise.

       CHECK_ROT = boolean
	      Check the molecular orbital rotation described above to ensure that no columns of the SCF eigenvector  matrix  are  swapped  by  the
	      rotation.  Has no effect if ROTATE = false.  The default is true.

       CHECK_MO_ORTHOGONALITY = boolean
	      Check if the molecular orbitals are orthonormal. Useful for debugging only.  The default is false.

       DIIS = boolean
	      This determines whether diis will be used.  The default is true.

       DIISSTART = integer
	      This gives the first iteration for which DIIS will be used.  The default is 0.

       NDIIS = integer
	      This  gives  the	number of error matrices to use in the diis procedure.	The default is 6 for closed shell, 4 for open shell, and 3
	      for tcscf.

       DIISDAMP = real
	      This gives the damping factor for the diis procedure.  The default is 0.0 for closed shell, 0.02 for open shell, and 0.01 for tcscf.

       INCR = real
	      This is used in tcscf to determine how often the ci coefficients are recalculated.  A small number (~0.25) will  cause  them  to	be
	      recalculated nearly every scf iteration.	The default is 0.25.

       DYN_ACC =  boolean
	      When performing direct scf this specifies whether dynamic integral accuracy cutoffs will be used.  Default is true (use dynamic cut-
	      offs).  Initial iterations are performed with integrals accurate to six digits.  After density is converged to 10^-5  or	30  itera-
	      tions  are completed, full integral accuracy is used.  If scf convergence problems are experienced disabling dynamic cutoffs by set-
	      ting this variable to false might help.

       ORTHOG_ONLY =  boolean
	      Sometimes in CASSCF or other non-HF/KS schemes for orbital optimization, it is useful to reorthogonalize MO's from other	geometries
	      for  the	current  geometry  so  they  can be used as an initial guess for the new MO's.	This can be performed by running CSCF with
	      ORTHOG_ONLY = true.  After the orbitals are orthogonalized, the program will quit without performing an SCF computation.	This  key-
	      word will be ignored if there are no previous orbitals in the checkpoint file.  Defaults to true if WFN = DETCAS.

								   30 May, 1991 							   cscf(1)