shell (c39b2)
Shell Decomposition
It is often desirable to decompose solvent around a solute
into shells. This module allows such a decomposition based on a distance
criterion.
* Syntax | The syntax of the SHELL command
* General | General overview
* Setup | Setup of overall SHELL parameters
* Update | Decomposing the current coordinates
* Define | Putting shell information into defines
* Statistics | Printing shell information
* Off | Turning SHELL off
* Correl | CORREL series using the SHELL module
* Caveats | Some limitations/todos to keep in mind
* Efficiency | Things to consider regarding speed
* Examples | Just what it says
It is often desirable to decompose solvent around a solute
into shells. This module allows such a decomposition based on a distance
criterion.
* Syntax | The syntax of the SHELL command
* General | General overview
* Setup | Setup of overall SHELL parameters
* Update | Decomposing the current coordinates
* Define | Putting shell information into defines
* Statistics | Printing shell information
* Off | Turning SHELL off
* Correl | CORREL series using the SHELL module
* Caveats | Some limitations/todos to keep in mind
* Efficiency | Things to consider regarding speed
* Examples | Just what it says
Top
Syntax for the SHELL command
[SYNTAX SHELL_decomposition]
Syntax:
SHELL [ NSHL int ] [ NOIMages ] [ ATOM ] -
[ SOLUte atom-selection ] [ SOLVent atom-selection ] -
[ SHTH real | SHBO real ... ]
[ UPDAte ]
[ DEFIne ] [ name ] [ SHELL int ]
[ BULK ]
[ SOLUte ]
[ SOLVent ]
[ STATistics ]
[ OFF ]
atom-selection::= » select
Syntax for the SHELL command
[SYNTAX SHELL_decomposition]
Syntax:
SHELL [ NSHL int ] [ NOIMages ] [ ATOM ] -
[ SOLUte atom-selection ] [ SOLVent atom-selection ] -
[ SHTH real | SHBO real ... ]
[ UPDAte ]
[ DEFIne ] [ name ] [ SHELL int ]
[ BULK ]
[ SOLUte ]
[ SOLVent ]
[ STATistics ]
[ OFF ]
atom-selection::= » select
Top
General overview
The SHELL module forms the basis of any shell based analysis
of solvent properties. It partitions all given SOLVent residues /
atoms into shells depending on the distance to the closest SOLUte atom
in the solute selection. The atom numbers of all atoms in a shell are
stored in a list which other modules, such as CORRel (
Correl:» chmdoc/correl ) can then use to compute properties of interest.
If images are set up SHELL will use SOLUte and SOLVent image
atoms for the distance criterion as well (although this can be switched
off explicitly by using the NOIMages keyword).
By default SHELL marks all atoms in a residue (even if
not all are included in the SOLVent selection) as being in the same
shell (if more than one atom of one residue is in the SOLVent selection
the lowest shell "wins"). This behavior can be altered by the ATOM
keyword. If present, only the atoms which are explicityl in the selection
will be partitioned.
General overview
The SHELL module forms the basis of any shell based analysis
of solvent properties. It partitions all given SOLVent residues /
atoms into shells depending on the distance to the closest SOLUte atom
in the solute selection. The atom numbers of all atoms in a shell are
stored in a list which other modules, such as CORRel (
Correl:» chmdoc/correl ) can then use to compute properties of interest.
If images are set up SHELL will use SOLUte and SOLVent image
atoms for the distance criterion as well (although this can be switched
off explicitly by using the NOIMages keyword).
By default SHELL marks all atoms in a residue (even if
not all are included in the SOLVent selection) as being in the same
shell (if more than one atom of one residue is in the SOLVent selection
the lowest shell "wins"). This behavior can be altered by the ATOM
keyword. If present, only the atoms which are explicityl in the selection
will be partitioned.
Top
SHELL decomposition setup
SHELL must be called once to set up the parameters before any
analysis can take place. The following parameters can be
used:
NSHL <int> - number of shells: into how many shells should the solvent
be divided (where every solvent atom beyond the last shell
is considered 'bulk')
default: 1
SHTH <real> - shell thickness: how thick (in A) is one shell (all shells
have the same thickness and an atom which is exactly (i *
SHTH) A from a solute atom is considered to be in the i+1th
shell).
default: 4.75A
SHBO <real...> - an alternative way to define the shell thickness: here
a real number must be given for each shell. Each number is
taken as the boundary of one shell to the next (so the numbers
should be in increasing order). This allows for shells of
different thickness.
ATOM - (optional) don't put whole residues (like a whole TIP3 water)
into the same shell, but only assign the atoms present in
the SOLVent selection to a shell ignoring residue
connectivity.
default: OFF
NOIMage - don't use image atoms in the decomposition process even if
images are set up (this will usually alter only shells at
the rim of the coordinates but if the solute itself is
located at the rim (where it can drift to during a
simulation) this may even alter 'inner' shells.
default: ON if images are set up and the image structure is
filled (e.g. by a previous call to 'ENERgy')
SOLUte - all atoms specified in the following selection are considered
as solute and will determine into which shell a solvent atom
is placed. (no default)
SOLVent - these atoms will be partitioned into the specified number of
shells. By default, a whole residue is in the lowest (innermost)
shell in which one of its atoms specified in this selection is
located. This can be altered by the ATOM keyword. (no default)
SHELL decomposition setup
SHELL must be called once to set up the parameters before any
analysis can take place. The following parameters can be
used:
NSHL <int> - number of shells: into how many shells should the solvent
be divided (where every solvent atom beyond the last shell
is considered 'bulk')
default: 1
SHTH <real> - shell thickness: how thick (in A) is one shell (all shells
have the same thickness and an atom which is exactly (i *
SHTH) A from a solute atom is considered to be in the i+1th
shell).
default: 4.75A
SHBO <real...> - an alternative way to define the shell thickness: here
a real number must be given for each shell. Each number is
taken as the boundary of one shell to the next (so the numbers
should be in increasing order). This allows for shells of
different thickness.
ATOM - (optional) don't put whole residues (like a whole TIP3 water)
into the same shell, but only assign the atoms present in
the SOLVent selection to a shell ignoring residue
connectivity.
default: OFF
NOIMage - don't use image atoms in the decomposition process even if
images are set up (this will usually alter only shells at
the rim of the coordinates but if the solute itself is
located at the rim (where it can drift to during a
simulation) this may even alter 'inner' shells.
default: ON if images are set up and the image structure is
filled (e.g. by a previous call to 'ENERgy')
SOLUte - all atoms specified in the following selection are considered
as solute and will determine into which shell a solvent atom
is placed. (no default)
SOLVent - these atoms will be partitioned into the specified number of
shells. By default, a whole residue is in the lowest (innermost)
shell in which one of its atoms specified in this selection is
located. This can be altered by the ATOM keyword. (no default)
Top
Updating SHELL
Once the shell parameters are set up, every time new
coordinates are read into the main coordinate set, the shell lists must
be updated by calling the 'SHELL UPDAte' command. The decomposition
is performed using a cubing based distance algorithm with a cube size of
NSHL * SHTH.
Updating SHELL
Once the shell parameters are set up, every time new
coordinates are read into the main coordinate set, the shell lists must
be updated by calling the 'SHELL UPDAte' command. The decomposition
is performed using a cubing based distance algorithm with a cube size of
NSHL * SHTH.
Top
Define
The individual shells as well as bulk or the solute or solvent
atoms can be converted to named selections which can then be used as
atom selections (analogue to the 'DEFIne <name> select ... end'
command). This allows output of single shell coordinates or general
access to the shells via the atom selection method.
Define
The individual shells as well as bulk or the solute or solvent
atoms can be converted to named selections which can then be used as
atom selections (analogue to the 'DEFIne <name> select ... end'
command). This allows output of single shell coordinates or general
access to the shells via the atom selection method.
Top
Statistics
The STATistics command prints the general shell parameter
currently in use and information about the shells.
At print level 6 or higher the atom numbers for all shells will
be printed and at print level 7 also the solute, solvent and bulk atom
numbers will be shown.
Statistics
The STATistics command prints the general shell parameter
currently in use and information about the shells.
At print level 6 or higher the atom numbers for all shells will
be printed and at print level 7 also the solute, solvent and bulk atom
numbers will be shown.
Top
CORREL series using SHELL
Currently two timeseries using shell are implemented:
- SDIP: syntax: ENTER <name> SDIP [SHELL int]
[BULK]
This generates a series with 4 entries: the X/Y/Z component of the
dipole moment and the number of atoms in this shell.
- SATM: syntax: ENTER <name> SATM [SHELL int] atom-spec
[BULK]
Generates a one-dimensional timeseries containing zero or one
indicating whether the atom is in the given shell or in the bulk at a
given timestep.
CORREL series using SHELL
Currently two timeseries using shell are implemented:
- SDIP: syntax: ENTER <name> SDIP [SHELL int]
[BULK]
This generates a series with 4 entries: the X/Y/Z component of the
dipole moment and the number of atoms in this shell.
- SATM: syntax: ENTER <name> SATM [SHELL int] atom-spec
[BULK]
Generates a one-dimensional timeseries containing zero or one
indicating whether the atom is in the given shell or in the bulk at a
given timestep.
Top
Caveats
- Currently only main coordinates are considered - there is no COMP
keyword. Since SHELL is mainly devised to be used with CORRel and
while reading trajectories this should not pose much of a problem
(although implementation of a 'SHELL UPDAte COMP' command should not
require many changes).
Caveats
- Currently only main coordinates are considered - there is no COMP
keyword. Since SHELL is mainly devised to be used with CORRel and
while reading trajectories this should not pose much of a problem
(although implementation of a 'SHELL UPDAte COMP' command should not
require many changes).
Top
Efficiency
The core of the SHELL UPDAte command is a cubing based algorithm
(adapted from M. Crowley's images/nbndgcm.src)
which is aware of SOLUte and SOLVent and thus calculates only distances
between SOLVent and SOLUte atoms. The efficiency of this approach is
influenced largely by the following parameters:
- SHTH and NSHL: the size of one cube is defined by SHTH * NSHL. If this
distance is large cubing will start to be inefficient and a brute
force approach may be more efficient.
- The number of atoms in the SOLVent and SOLUte selections: if only one
atom of a residue is considered 'decisive' for a whole residue the
number of pairs to sample can be greatly reduced. E.g., if only the
oxygen of TIP3 water is selected as SOLVent the number of SOLVent
atoms is reduced by a factor 3 while by default all water atoms are marked
as belonging to a shell (unless ATOM is set; then it is necessary to select
all water atoms, see examples).
Efficiency
The core of the SHELL UPDAte command is a cubing based algorithm
(adapted from M. Crowley's images/nbndgcm.src)
which is aware of SOLUte and SOLVent and thus calculates only distances
between SOLVent and SOLUte atoms. The efficiency of this approach is
influenced largely by the following parameters:
- SHTH and NSHL: the size of one cube is defined by SHTH * NSHL. If this
distance is large cubing will start to be inefficient and a brute
force approach may be more efficient.
- The number of atoms in the SOLVent and SOLUte selections: if only one
atom of a residue is considered 'decisive' for a whole residue the
number of pairs to sample can be greatly reduced. E.g., if only the
oxygen of TIP3 water is selected as SOLVent the number of SOLVent
atoms is reduced by a factor 3 while by default all water atoms are marked
as belonging to a shell (unless ATOM is set; then it is necessary to select
all water atoms, see examples).
Top
Examples
SHELL NSHL 4 SHTH 3.5 SOLU SELE RESNAME ALA END -
SOLV SELE RESNAME TIP3 .AND. TYPE OH2 END
Puts all TIP3 waters into 4 shells - each 3.5A thick - around all
ALAnines. Only the TIP3 oxygen (OH2) are considered for the solvent so
each water will be in the shell its oxygen is in.
SHELL NSHL 4 SHTH 3.5 ATOM SOLU SELE RESNAME ALA END -
SOLV SELE RESNAME TIP3 END
the same as above but every atom is considered individually so at a shell
interface one or both hydrogens can be in one shell while the oxygen is
in the other.
Examples
SHELL NSHL 4 SHTH 3.5 SOLU SELE RESNAME ALA END -
SOLV SELE RESNAME TIP3 .AND. TYPE OH2 END
Puts all TIP3 waters into 4 shells - each 3.5A thick - around all
ALAnines. Only the TIP3 oxygen (OH2) are considered for the solvent so
each water will be in the shell its oxygen is in.
SHELL NSHL 4 SHTH 3.5 ATOM SOLU SELE RESNAME ALA END -
SOLV SELE RESNAME TIP3 END
the same as above but every atom is considered individually so at a shell
interface one or both hydrogens can be in one shell while the oxygen is
in the other.