CHARMM c32b1 tps.doc



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                     Transition Path Sampling 

The Transition Path Sampling (TPS) methods introduced by Chandler and   
co-workers to sample rare events (see References) are implemented as 
extensions of the RXNCoor, DYNAmics, and USER commands in CHARMM.  The 
TPS keyword must be included in pref.dat for the code to be compiled.

* Menu:

* Syntax::              Syntax required to invoke TPS
* Description::         Description of TPS specific keywords
* References::          Some references of use



File: tps ]-[ Node: Syntax
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                    Syntax required to invoke TPS

[Syntax RXNCoor]

RXNCoor [ standard RXNCoor keywords ] [ set-spec ] [ bas-spec ] [wri-spec]

set-spec ::= SET [ NRXN     1 ] NRXN{ name }

             where NRXN{ name } is an NRXN-long list of the names of 
             the order parameters to calculate.

bas-spec ::= BASIn NRXN{ name alo ahi blo bhi }

wri-spec ::= TPUNit NRXN{ name unit }

[Syntax DYNAmics]

DYNAmics [ RTRJ ] [ standard DYNAmics keywords ] -
         PATH [ mod-spec ] [ tps-spec ] [ sht-spec ] [ trj-spec ] [ hsa-spec ]

mod-spec ::= [ ISVFrequency 0 ]

tps-spec ::= [ NTPAth      0 ] [ NSAVP        0 ] [ NPRAccept         0 ] -
             [ ITPRint     0 ] [ ITPUnit STDOUT ] [ ACCU         STDOUT ] -
             [ USER        0 ] [ PSHOot     1.0 ] [ IMXShift          1 ] 
             [ SDUNit      0 ] [ SDINit       0 ] 

sht-spec ::= [ VFRAction 0.0 ] [ TFRAction  1.0 ] [ NTFRaction   NTPAth ] -
             [ IFSHoot    -1 ] [ IRST         0 ] [ PHALf             0 ] -
             [ ISLO        0 ] [ ISLN         0 ]  

trj-spec ::= [ NUNIt       1 ] [ IFIRst      -1 ] [ VFIRst IFIRst+NUNIt ] -
             [ BEGIn       0 ] [ SKIP        -1 ] [ STOP              0 ]  

hsa-spec ::= [ HSAM        0 ] [ IHUN    STDOUT ] [ IHFR              0 ] -
             [ NHSV       -1 ] [ IHPR         1 ] [ NHST              0 ] 
             



File: tps ]-[ Node: Description
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                                 RXNCoor                              

     The RXNCoor command has been modified to facilitate the definition of the
basins that constrain the endpoints of the path.  

     Multiple order parameters can be specified using the NRXN keyword
following the SET keyword (see umbrel.doc for a description of the
latter).  However, note that the tree structure associated with the
RXNCoor command is not dynamically allocated, so that MAXNOD in
rxncom.fcm must be increased with for larger numbers of order parameters.

     The BASIn keyword is used to specify the boundaries of the basins (A
and B).  For each order parameter, one must give the name followed by
four real numbers: alo, ahi, blo, and bhi (the order is important).
Here, alo (blo) is the lower bound for basin A (B) and ahi (bhi) is
the upper bound for basin A (B).

     The TPUNit keyword designates units to which values of the order
parameters are written.  Values are written for each saved trajectory.
A unit number less than 1 suppresses writeout.

                                 DYNAmics

     The DYNAmics command has been modified to provide a looping structure to
calculate multiple trajectories (paths).  TPS is invoked by including the PATH
keyword.

The additional keywords that are specific to TPS are:

     NTPAth      The number of paths to calculate.

     NSAVP       The frequency of saving paths to the trajectory and velocity 
                 files.

     USER        Whether to user USERSB to calculated the order parameters
                 used to determine the stable states. 

     ITPRint     The frequency with which to write order parameter values
                 at basin evaluations.

     ITPUnit     The unit number on which to write order parameter values 
                 at basin evaluations.

     SDUNit      The unit number to which to write  random number generator 
                 seeds for TPS with Langevin dynamics.

     SDINit      The unit number from which to read random number generator 
                 seeds for TPS with Langevin dynamics.
   
     NPRAccept   The frequency of printing acceptance statistics.

     ACCUnit     The unit number to which to write acceptance statistics
                 as a function of saved structure.  The columns are the same
                 as those printed by TPSACC to the CHARMM output file.

     PSHOot      The fraction of moves that are shooting moves.

     IMXShift    The maximum number of saved phase space points by which to 
                 reptate the path in a shifting move.   In other words, a 
                 shift can be up to IMXS*NSAVC molecular dynamics steps long.

     VFRAction   The amount to perturb the velocities in shooting moves.  A 
                 random vector is chosen from a Gaussian (Maxwell-Boltzmann) 
                 distribution and then scaled by VFRAction.  The scaled vector 
                 is added to the current velocity vector and the result is 
                 scaled to conserve kinetic energy after correcting for SHAKE 
                 if necessary.  This procedure has the effect of rotating the 
                 3N-dimensional velocity vector without changing its magnitude.

     TFRAction   The amount by which to scale the kinetic energy in each 
                 shooting move if annealing is desired.

     NTFRaction  The number of ACCEPTED shooting moves in which to scale the 
                 kinetic energy by TFRAction.  

     IFSHoot     The first point from which to shoot in units of NSAVC.  A 
                 value of -1 indicates that IFSHot is chosen randomly if RTRJ 
                 is specified and it is set to the middle of the path
                 if shooting from a structure.

     IRST        The saved phase space point to save to the restart file.  It 
                 is best if IRST is chosen to be close to the transition state.
                 Otherwise, numerical errors can prevent one from regenerating 
                 a valid path using the saved phase space point.

     PHALf       The probability of shooting half a trajectory.  A stochastic
                 element should be included if PHALf is greater than
                 zero.  For example, see discussion about Langevin dynamics.

     ISLO        The lowest saved structure from which to shoot.

     ISLN        The number of saved structures from which to shoot (i.e.,
                 the last saved structure shot from is ISLO + ISLN - 1).

     RTRJ        If this keyword is present (in place of STARt or RESTart), 
                 an entire trajectory is read at the beginning of a restart.  
                 The keywords BEGIn, SKIP, and STOP have their usual meaning.
                 
     NUNIt       The number of trajectory files to read if RTRJ is specified.

     IFIRst      The first trajectory file to read if RTRJ is specified.

     VFIRst      The first velocity   file to read if RTRJ is specified.

     HSAMple     If this keyword is present, paths are accepted if they 
                 start in basin A and ever go through basin B.  Also, the 
                 probability that the system is in basin B as a function of 
                 time is calculated [<h_B(t)>].

     NHSTart     The path at which to start calculating <h_B(t)>.

     IHUNit      The unit number to which to write <h_B(t)>.

     IHFRequency The frequency with which to write <h_B(t)>.

     NHSV        The frequency of evaluating whether the path is in 
                 basin B (h_B[x(t)]).  A value of -1 sets NHSV to NSAVC.

     IHPRint     h_B[x(t)] is printed every IHPRint*NHSV steps.

     

In addition, note that the meaning of the ISVFrequency keyword is changed
during TPS.  It refers to the number of PATHS, not the the number of 
molecular dynamics steps, between writes to the restart file.  

Note that if PHALf is greater than 0, shooting moves are carried out in 
which the path is only updated in one direction.  In this case a stochastic 
element should be included in the integration, such as Langevin dynamics. 
It is possible to apply Langevin integration to only the periphery of the 
simulation using the RBUF keyword.  When using Langevin dynamics with TPS, 
the random number seed used to generate the random forces is recorded for 
every saved structure.  This is necessary to regenerate the appropriate 
displacement vectors from the coordinates and velocities in 2-step dynamics 
during a shooting move. When writing and reading trajectories, these seeds 
can be written/read as designated by the keywords SDUNit and SDINit. If 
seeds are not read in with a trajectory, seeds are generated randomly for 
the initial shooting move, which results in a different displacement vector 
than in the original structure. If SHAKe is used in conjunction with Langevin 
dynamics, the new displacement vectors have some velocity components along 
the constrained bond.  These components are zeroed, and the overall kinetic 
energy will be reduced for that step.  Also note that, if SHAKe is used, 
there is a small error in the regeneration of  displacement vectors for 
atoms that have different values of FBETA and are connected by a shaken bond.




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                                REFERENCES

(1) Dellago, C., Bolhuis, P., Csajka, F. and Chandler, D. (1998)
    Transition Path Sampling and the Calculation of Rate Constants.
    J. Chem. Phys . 108, 1964.

(2) Dellago, C., Bolhuis, P. and Chandler, D. (1998) Efficient
    Transition Path Sampling:  Application to Lennard-Jones Cluster
    Rearrangements.  J. Chem. Phys. 108, 9236.

(3) Dellago C., Bolhuis, P. G., Geissler, P. L. (2002) Transition path
    sampling. Adv. Chem. Phys. 123, 1.

(4) Bolhuis, P. G., Chandler, D., Dellago, C. and Geissler, P. (2002)
    Transition Path Sampling: Throwing ropes over mountain passes, in
    the dark.  Ann. Rev. Phys. Chem. 59, 291.

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